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1 %% This BibTeX bibliography file was created using BibDesk.
2 %% http://bibdesk.sourceforge.net/
3
4
5 %% Created for Dan Gezelter at 2014-04-11 14:26:52 -0400
6
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8 %% Saved with string encoding Unicode (UTF-8)
9
10
11 @string{acp = {Adv. Chem. Phys.}}
12
13 @string{bj = {Biophys. J.}}
14
15 @string{ccp5 = {CCP5 Information Quarterly}}
16
17 @string{cp = {Chem. Phys.}}
18
19 @string{cpl = {Chem. Phys. Lett.}}
20
21 @string{ea = {Electrochim. Acta}}
22
23 @string{jacs = {J. Am. Chem. Soc.}}
24
25 @string{jbc = {J. Biol. Chem.}}
26
27 @string{jcat = {J. Catalysis}}
28
29 @string{jcc = {J. Comp. Chem.}}
30
31 @string{jcop = {J. Comp. Phys.}}
32
33 @string{jcp = {J. Chem. Phys.}}
34
35 @string{jctc = {J. Chem. Theory Comp.}}
36
37 @string{jmc = {J. Med. Chem.}}
38
39 @string{jml = {J. Mol. Liq.}}
40
41 @string{jmm = {J. Mol. Model.}}
42
43 @string{jpc = {J. Phys. Chem.}}
44
45 @string{jpca = {J. Phys. Chem. A}}
46
47 @string{jpcb = {J. Phys. Chem. B}}
48
49 @string{jpcc = {J. Phys. Chem. C}}
50
51 @string{jpcl = {J. Phys. Chem. Lett.}}
52
53 @string{mp = {Mol. Phys.}}
54
55 @string{pams = {Proc. Am. Math Soc.}}
56
57 @string{pccp = {Phys. Chem. Chem. Phys.}}
58
59 @string{pnas = {Proc. Natl. Acad. Sci. USA}}
60
61 @string{pr = {Phys. Rev.}}
62
63 @string{pra = {Phys. Rev. A}}
64
65 @string{prb = {Phys. Rev. B}}
66
67 @string{pre = {Phys. Rev. E}}
68
69 @string{prl = {Phys. Rev. Lett.}}
70
71 @string{rmp = {Rev. Mod. Phys.}}
72
73 @string{ss = {Surf. Sci.}}
74
75
76 @article{Alaghemandi:2011pi,
77 Author = {Alaghemandi, Mohammad and M{\"u}ller-Plathe, Florian and B{\"o}hm, Michael C.},
78 Date-Added = {2014-04-10 21:16:36 +0000},
79 Date-Modified = {2014-04-11 17:53:56 +0000},
80 Doi = {http://dx.doi.org/10.1063/1.3660348},
81 Eid = 184905,
82 Journal = {J. Chem. Phys.},
83 Number = {18},
84 Pages = {184905-1 - 9},
85 Title = {Thermal conductivity of carbon nanotube---polyamide-6,6 nanocomposites: Reverse non-equilibrium molecular dynamics simulations},
86 Url = {http://scitation.aip.org/content/aip/journal/jcp/135/18/10.1063/1.3660348},
87 Volume = {135},
88 Year = {2011},
89 Bdsk-Url-1 = {http://scitation.aip.org/content/aip/journal/jcp/135/18/10.1063/1.3660348},
90 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.3660348}}
91
92 @article{MORALES:1998fk,
93 Author = {D.~M. Heyes and M.~J. Nuevo and J.~J. Morales},
94 Date-Added = {2014-04-10 19:27:24 +0000},
95 Date-Modified = {2014-04-10 19:54:50 +0000},
96 Doi = {10.1080/002689798168682},
97 Eprint = {http://www.tandfonline.com/doi/pdf/10.1080/002689798168682},
98 Journal = {Mol. Phys.},
99 Number = {6},
100 Pages = {985-994},
101 Title = {Translational and rotational diffusion of dilute solid amorphous spherical nanocolloids by molecular dynamics simulation},
102 Url = {http://www.tandfonline.com/doi/abs/10.1080/002689798168682},
103 Volume = {93},
104 Year = {1998},
105 Bdsk-Url-1 = {http://www.tandfonline.com/doi/abs/10.1080/002689798168682},
106 Bdsk-Url-2 = {http://dx.doi.org/10.1080/002689798168682}}
107
108 @article{Rotne1969,
109 Author = {F. Perrin},
110 Date-Added = {2014-04-10 18:55:23 +0000},
111 Date-Modified = {2014-04-10 18:55:23 +0000},
112 Journal = {J. Chem. Phys.},
113 Pages = {4831-4837},
114 Title = {Variational treatment of hydrodynamic interaction in polymers},
115 Volume = 50,
116 Year = 1969}
117
118 @article{Perrin1936,
119 Author = {F. Perrin},
120 Date-Added = {2014-04-10 18:55:23 +0000},
121 Date-Modified = {2014-04-11 18:26:42 +0000},
122 Journal = {J. Phys. Radium},
123 Pages = {1-11},
124 Title = {Mouvement Brownien d'un ellipsoid(II). Rotation libre et depolarisation des fluorescences. Translation et diffusion de moleculese ellipsoidales},
125 Volume = 7,
126 Year = 1936}
127
128 @article{Perrin1934,
129 Author = {F. Perrin},
130 Date-Added = {2014-04-10 18:55:23 +0000},
131 Date-Modified = {2014-04-11 18:26:49 +0000},
132 Journal = {J. Phys. Radium},
133 Pages = {497-511},
134 Title = {Mouvement Brownien d'un ellipsoid(I). Dispersion dielectrique pour des molecules ellipsoidales},
135 Volume = 5,
136 Year = 1934}
137
138 @article{Jeffery:1915fk,
139 Author = {Jeffery, G. B.},
140 Date-Added = {2014-03-14 19:37:02 +0000},
141 Date-Modified = {2014-03-14 19:40:55 +0000},
142 Doi = {10.1112/plms/s2_14.1.327},
143 Eprint = {http://plms.oxfordjournals.org/content/s2_14/1/327.full.pdf+html},
144 Journal = {Proceedings of the London Mathematical Society},
145 Number = {1242},
146 Pages = {327-338},
147 Title = {On the Steady Rotation of a Solid of Revolution in a Viscous Fluid},
148 Url = {http://plms.oxfordjournals.org/content/s2_14/1/327.short},
149 Volume = {series 2, volume 14},
150 Year = {1915},
151 Bdsk-Url-1 = {http://plms.oxfordjournals.org/content/s2_14/1/327.short},
152 Bdsk-Url-2 = {http://dx.doi.org/10.1112/plms/s2_14.1.327}}
153
154 @article{Schmidt:2003kx,
155 Abstract = {Using molecular dynamics computer simulation, we have calculated the velocity autocorrelation function and diffusion constant for a spherical solute in a dense fluid of spherical solvent particles. The size and mass of the solute particle are related in such a way that we can naturally approach the Brownian limit (when the solute becomes much larger and more massive than the solvent particles). We find that as long as the solute radius is interpreted as an effective hydrodynamic radius, the Stokes-Einstein law with slip boundary conditions is satisfied as the Brownian limit is approached (specifically, when the solute is roughly 100 times more massive than the solvent particles). In contrast, the Stokes-Einstein law is not satisfied for a tagged particle of the neat solvent. We also find that in the Brownian limit the amplitude of the long-time tail of the solute's velocity autocorrelation function is in good agreement with theoretical hydrodynamic predictions. When the solvent density is substantially lower than the triple density, the Stokes-Einstein law is no longer satisfied, and the amplitude of the long-time tail is not in good agreement with theoretical predictions, signaling the breakdown of hydrodynamics. (C) 2003 American Institute of Physics.},
156 Author = {Schmidt, JR and Skinner, JL},
157 Date-Added = {2014-03-14 18:36:17 +0000},
158 Date-Modified = {2014-03-15 21:42:15 +0000},
159 Doi = {DOI 10.1063/1.1610442},
160 Journal = jcp,
161 Pages = {8062-8068},
162 Title = {Hydrodynamic Boundary Conditions, the Stokes-Einstein Law, and Long-Time Tails in the Brownian Limit},
163 Volume = 119,
164 Year = 2003,
165 Bdsk-Url-1 = {http://dx.doi.org/10.1063/1.1610442}}
166
167 @article{Schmidt:2004fj,
168 Abstract = {Using molecular dynamics computer simulation, we have calculated the velocity autocorrelation function and diffusion constant for a variety of solutes in a dense fluid of spherical solvent particles. We explore the effects of surface roughness of the solute on the resulting hydrodynamic boundary condition as we naturally approach the Brownian limit (when the solute becomes much larger and more massive than the solvent particles). We find that when the solute and solvent interact through a purely repulsive isotropic potential, in the Brownian limit the Stokes-Einstein law is satisfied with slip boundary conditions. However, when surface roughness is introduced through an anisotropic solute-solvent interaction potential, we find that the Stokes-Einstein law is satisfied with stick boundary conditions. In addition, when the attractive strength of a short-range isotropic solute-solvent potential is increased, the solute becomes dressed with solvent particles, making it effectively rough, and so stick boundary conditions are again recovered.},
169 Author = {Schmidt, JR and Skinner, JL},
170 Date-Added = {2014-03-14 18:36:17 +0000},
171 Date-Modified = {2014-03-15 21:41:38 +0000},
172 Doi = {DOI 10.1021/jp037185r},
173 Journal = jpcb,
174 Pages = {6767-6771},
175 Title = {Brownian Motion of a Rough Sphere and the Stokes-Einstein Law},
176 Volume = 108,
177 Year = 2004,
178 Bdsk-Url-1 = {http://dx.doi.org/10.1021/jp037185r}}
179
180 @article{Lervik:2009fk,
181 Abstract = {We investigate{,} using transient non-equilibrium molecular-dynamics simulations{,} heat-transfer through nanometer-scale interfaces consisting of n-decane (2-12 nm diameter) droplets in water. Using computer simulation results of the temperature relaxation of the nanodroplet as a function of time we have computed the thermal conductivity and the interfacial conductance of the droplet and the droplet/water interface respectively. We find that the thermal conductivity of the n-decane droplets is insensitive to droplet size{,} whereas the interfacial conductance shows a strong dependence on the droplet radius. We rationalize this behavior in terms of a modification of the n-decane/water surface-tension with droplet curvature. This enhancement in interfacial conductance would contribute{,} in the case of a suspension{,} to an increase in the thermal conductivity with decreasing particle radius. This notion is consistent with recent experimental studies of nanofluids. We also investigate the accuracy of different diffusion equations to model the temperature relaxation in non stationary non equilibrium processes. We show that the modeling of heat transfer across a nanodroplet/fluid interface requires the consideration of the thermal conductivity of the nanodroplet as well as the temperature discontinuity across the interface. The relevance of this result in diffusion models that neglect thermal conductivity effects in the modeling of the temperature relaxation is discussed.},
182 Author = {Lervik, Anders and Bresme, Fernando and Kjelstrup, Signe},
183 Date-Added = {2014-03-14 17:33:22 +0000},
184 Date-Modified = {2014-03-15 21:40:38 +0000},
185 Doi = {10.1039/B817666C},
186 Issue = {12},
187 Journal = {Soft Matter},
188 Pages = {2407-2414},
189 Publisher = {The Royal Society of Chemistry},
190 Title = {Heat Transfer in Soft Nanoscale Interfaces: The Influence of Interface Curvature},
191 Url = {http://dx.doi.org/10.1039/B817666C},
192 Volume = {5},
193 Year = {2009},
194 Bdsk-Url-1 = {http://dx.doi.org/10.1039/B817666C}}
195
196 @article{Vogelsang:1988qv,
197 Author = {Vogelsang, R. and Hoheisel, G. and Luckas, M.},
198 Date-Added = {2014-03-13 20:40:44 +0000},
199 Date-Modified = {2014-04-10 19:56:04 +0000},
200 Doi = {10.1080/00268978800100813},
201 Eprint = {http://www.tandfonline.com/doi/pdf/10.1080/00268978800100813},
202 Journal = {Mol. Phys.},
203 Number = {6},
204 Pages = {1203-1213},
205 Title = {Shear Viscosity and Thermal Conductivity of the Lennard-Jones Liquid Computed Using Molecular Dynamics and Predicted by a Memory Function Model for a Large Number of States},
206 Url = {http://www.tandfonline.com/doi/abs/10.1080/00268978800100813},
207 Volume = {64},
208 Year = {1988},
209 Bdsk-Url-1 = {http://www.tandfonline.com/doi/abs/10.1080/00268978800100813},
210 Bdsk-Url-2 = {http://dx.doi.org/10.1080/00268978800100813}}
211
212 @article{Berendsen87,
213 Author = {Berendsen, H. J. C. and Grigera, J. R. and Straatsma, T. P.},
214 Date-Added = {2014-03-13 15:02:07 +0000},
215 Date-Modified = {2014-04-10 19:56:52 +0000},
216 Doi = {10.1021/j100308a038},
217 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/j100308a038},
218 Journal = {J. Phys. Chem.},
219 Number = {24},
220 Pages = {6269-6271},
221 Title = {The Missing Term in Effective Pair Potentials},
222 Url = {http://pubs.acs.org/doi/abs/10.1021/j100308a038},
223 Volume = {91},
224 Year = {1987},
225 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/j100308a038},
226 Bdsk-Url-2 = {http://dx.doi.org/10.1021/j100308a038}}
227
228 @article{Stocker:2013cl,
229 Author = {Stocker, Kelsey M. and Gezelter, J. Daniel},
230 Date-Added = {2014-03-13 14:20:18 +0000},
231 Date-Modified = {2014-04-10 19:56:33 +0000},
232 Doi = {10.1021/jp312734f},
233 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/jp312734f},
234 Journal = {J. Phys. Chem. C},
235 Number = {15},
236 Pages = {7605-7612},
237 Title = {Simulations of Heat Conduction at Thiolate-Capped Gold Surfaces: The Role of Chain Length and Solvent Penetration},
238 Url = {http://pubs.acs.org/doi/abs/10.1021/jp312734f},
239 Volume = {117},
240 Year = {2013},
241 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/jp312734f},
242 Bdsk-Url-2 = {http://dx.doi.org/10.1021/jp312734f}}
243
244 @article{Picalek:2009rz,
245 Abstract = {Temperature dependence of viscosity of butyl-3-methylimidazolium
246 hexafluorophosphate is investigated by non-equilibrium molecular
247 dynamics simulations with cosine-modulated force in the temperature
248 range from 360 to 480K. It is shown that this method is able to
249 correctly predict the shear viscosity. The simulation setting and
250 choice of the force field are discussed in detail. The all-atom force
251 field exhibits a bad convergence and the shear viscosity is
252 overestimated, while the simple united atom model predicts the kinetics
253 very well. The results are compared with the equilibrium molecular
254 dynamics simulations. The relationship between the diffusion
255 coefficient and viscosity is examined by means of the hydrodynamic
256 radii calculated from the Stokes-Einstein equation and the solvation
257 properties are discussed.},
258 Address = {4 PARK SQUARE, MILTON PARK, ABINGDON OX14 4RN, OXON, ENGLAND},
259 Affiliation = {Kolafa, J (Reprint Author), Prague Inst Chem Technol, Dept Phys Chem, CR-16628 Prague, Czech Republic. {[}Picalek, Jan; Kolafa, Jiri] Prague Inst Chem Technol, Dept Phys Chem, CR-16628 Prague, Czech Republic.},
260 Author = {Picalek, Jan and Kolafa, Jiri},
261 Author-Email = {jiri.kolafa@vscht.cz},
262 Date-Added = {2014-03-13 14:11:53 +0000},
263 Date-Modified = {2014-03-15 21:39:56 +0000},
264 Doc-Delivery-Number = {448FD},
265 Doi = {10.1080/08927020802680703},
266 Funding-Acknowledgement = {Czech Science Foundation {[}203/07/1006]; Czech Ministry of Education {[}LC512]},
267 Funding-Text = {We gratefully acknowledge a support from the Czech Science Foundation (project 203/07/1006) and the computing facilities from the Czech Ministry of Education (Center for Biomolecules and Complex Molecular Systems, project LC512).},
268 Issn = {0892-7022},
269 Journal = {Mol. Simul.},
270 Journal-Iso = {Mol. Simul.},
271 Keywords = {room temperature ionic liquids; viscosity; non-equilibrium molecular dynamics; solvation; imidazolium},
272 Keywords-Plus = {1-N-BUTYL-3-METHYLIMIDAZOLIUM HEXAFLUOROPHOSPHATE; PHYSICOCHEMICAL PROPERTIES; COMPUTER-SIMULATION; PHYSICAL-PROPERTIES; IMIDAZOLIUM CATION; FORCE-FIELD; AB-INITIO; TEMPERATURE; CHLORIDE; CONDUCTIVITY},
273 Language = {English},
274 Number = {8},
275 Number-Of-Cited-References = {50},
276 Pages = {685-690},
277 Publisher = {TAYLOR \& FRANCIS LTD},
278 Subject-Category = {Chemistry, Physical; Physics, Atomic, Molecular \& Chemical},
279 Times-Cited = {2},
280 Title = {Shear Viscosity of Ionic Liquids from Non-Equilibrium Molecular Dynamics Simulation},
281 Type = {Article},
282 Unique-Id = {ISI:000266247600008},
283 Volume = {35},
284 Year = {2009},
285 Bdsk-Url-1 = {http://dx.doi.org/10.1080/08927020802680703%7D}}
286
287 @article{Backer:2005sf,
288 Author = {J. A. Backer and C. P. Lowe and H. C. J. Hoefsloot and P. D. Iedema},
289 Date-Added = {2014-03-13 14:11:38 +0000},
290 Date-Modified = {2014-03-15 21:39:20 +0000},
291 Doi = {10.1063/1.1883163},
292 Eid = {154503},
293 Journal = {J. Chem. Phys.},
294 Keywords = {Poiseuille flow; flow simulation; Lennard-Jones potential; viscosity; boundary layers; computational fluid dynamics},
295 Number = {15},
296 Numpages = {6},
297 Pages = {154503},
298 Publisher = {AIP},
299 Title = {Poiseuille Flow to Measure the Viscosity of Particle Model Fluids},
300 Url = {http://link.aip.org/link/?JCP/122/154503/1},
301 Volume = {122},
302 Year = {2005},
303 Bdsk-Url-1 = {http://link.aip.org/link/?JCP/122/154503/1},
304 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.1883163}}
305
306 @article{Vasquez:2004ty,
307 Abstract = {A method for fast calculation of viscosity from molecular dynamics simulation is revisited. The method consists of using a steady-state periodic perturbation. A methodology to choose the amplitude of the external perturbation, which is one of the major practical issues in the original technique of Gosling et al. {$[$}Mol. Phys. 26: 1475 (1973){$]$} is proposed. The amplitude of the perturbation required for fast caculations and the viscosity values for wide ranges of temperature and density of the Lennard-Jones (LJ) model fluid are reported. The viscosity results are in agreement with recent LJ viscosity calculations. Additionally, the simulations demonstrate that the proposed approach is suitable to efficiently generate viscosity data of good quality.},
308 Author = {Vasquez, V. R. and Macedo, E. A. and Zabaloy, M. S.},
309 Date = {2004/11/02/},
310 Date-Added = {2014-03-13 14:11:31 +0000},
311 Date-Modified = {2014-03-13 14:12:08 +0000},
312 Day = {02},
313 Journal = {Int. J. Thermophys.},
314 M3 = {10.1007/s10765-004-7736-3},
315 Month = {11},
316 Number = {6},
317 Pages = {1799--1818},
318 Title = {Lennard-Jones Viscosities in Wide Ranges of Temperature and Density: Fast Calculations Using a Steady--State Periodic Perturbation Method},
319 Ty = {JOUR},
320 Url = {http://dx.doi.org/10.1007/s10765-004-7736-3},
321 Volume = {25},
322 Year = {2004},
323 Bdsk-Url-1 = {http://dx.doi.org/10.1007/s10765-004-7736-3}}
324
325 @article{Hess:2002nr,
326 Author = {Berk Hess},
327 Date-Added = {2014-03-13 14:11:23 +0000},
328 Date-Modified = {2014-03-15 21:38:44 +0000},
329 Doi = {10.1063/1.1421362},
330 Journal = {J. Chem. Phys.},
331 Keywords = {viscosity; molecular dynamics method; liquid theory; shear flow},
332 Number = {1},
333 Pages = {209-217},
334 Publisher = {AIP},
335 Title = {Determining the Shear Viscosity of Model Liquids from Molecular Dynamics Simulations},
336 Url = {http://link.aip.org/link/?JCP/116/209/1},
337 Volume = {116},
338 Year = {2002},
339 Bdsk-Url-1 = {http://link.aip.org/link/?JCP/116/209/1},
340 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.1421362}}
341
342 @article{Romer2012,
343 Author = {R{\"o}mer, Frank and Lervik, Anders and Bresme, Fernando},
344 Date-Added = {2014-01-08 20:51:36 +0000},
345 Date-Modified = {2014-01-08 20:53:28 +0000},
346 Journal = {J. Chem. Phys.},
347 Pages = {074503-1 - 8},
348 Title = {Nonequilibrium Molecular Dynamics Simulations of the Thermal Conductivity of Water: A Systematic Investigation of the SPC/E and TIP4P/2005 Models},
349 Volume = {137},
350 Year = {2012}}
351
352 @article{Zhang2005,
353 Author = {Zhang, Meimei and Lussetti, Enrico and de Souza, Lu{\'\i}s and M\"{u}ller-Plathe, Florian},
354 Date-Added = {2014-01-08 20:49:09 +0000},
355 Date-Modified = {2014-01-08 20:51:28 +0000},
356 Journal = {J. Phys. Chem. B},
357 Pages = {15060-15067},
358 Title = {Thermal Conductivities of Molecular Liquids by Reverse Nonequilibrium Molecular Dynamics},
359 Volume = {109},
360 Year = {2005}}
361
362 @article{Vardeman2011,
363 Author = {Charles F. Vardeman and Kelsey M. Stocker and J. Daniel Gezelter},
364 Date-Added = {2013-09-05 23:48:02 +0000},
365 Date-Modified = {2013-09-05 23:48:02 +0000},
366 Journal = {J. Chem. Theory Comput.},
367 Keywords = {Langevin Hull},
368 Pages = {834-842},
369 Title = {The Langevin Hull: Constant Pressure and Temperature Dynamics for Nonperiodic Systems},
370 Volume = {7},
371 Year = {2011},
372 Bdsk-File-1 = {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}}
373
374 @article{EDELSBRUNNER:1994oq,
375 Abstract = {Frequently, data in scientific computing is in its abstract form a finite point set in space, and it is sometimes useful or required to compute what one might call the ''shape'' of the set. For that purpose, this article introduces the formal notion of the family of alpha-shapes of a finite point set in R3. Each shape is a well-defined polytope, derived from the Delaunay triangulation of the point set, with a parameter alpha is-an-element-of R controlling the desired level of detail. An algorithm is presented that constructs the entire family of shapes for a given set of size n in time O(n2), worst case. A robust implementation of the algorithm is discussed, and several applications in the area of scientific computing are mentioned.},
376 Address = {1515 BROADWAY, NEW YORK, NY 10036},
377 Author = {Edelsbrunner, H and Mucke, E.~P.},
378 Date = {JAN 1994},
379 Date-Added = {2013-09-05 23:47:03 +0000},
380 Date-Modified = {2013-09-05 23:47:03 +0000},
381 Journal = {ACM Trans. Graphics},
382 Keywords = {COMPUTATIONAL GRAPHICS; DELAUNAY TRIANGULATIONS; GEOMETRIC ALGORITHMS; POINT SETS; POLYTOPES; ROBUST IMPLEMENTATION; SCIENTIFIC COMPUTING; SCIENTIFIC VISUALIZATION; SIMPLICIAL COMPLEXES; SIMULATED PERTURBATION; 3-DIMENSIONAL SPACE},
383 Pages = {43-72},
384 Publisher = {ASSOC COMPUTING MACHINERY},
385 Timescited = {270},
386 Title = {3-DIMENSIONAL ALPHA-SHAPES},
387 Volume = {13},
388 Year = {1994}}
389
390 @article{Barber96,
391 Author = {C.~B. Barber and D.~P. Dobkin and H.~T. Huhdanpaa},
392 Date-Added = {2013-09-05 23:46:55 +0000},
393 Date-Modified = {2013-09-05 23:46:55 +0000},
394 Journal = {ACM Trans. Math. Software},
395 Pages = {469-483},
396 Title = {The Quickhull Algorithm for Convex Hulls},
397 Volume = 22,
398 Year = 1996}
399
400 @article{Sun2008,
401 Author = {Xiuquan Sun and Teng Lin and J. Daniel Gezelter},
402 Date-Added = {2013-09-05 20:13:18 +0000},
403 Date-Modified = {2013-09-05 20:14:17 +0000},
404 Journal = {J. Chem. Phys.},
405 Pages = {234107},
406 Title = {Langevin Dynamics for Rigid Bodies of Arbitrary Shape},
407 Volume = {128},
408 Year = {2008}}
409
410 @article{Zwanzig,
411 Author = {ChihMing Hu and Robert Zwanzig},
412 Date-Added = {2013-09-05 20:11:32 +0000},
413 Date-Modified = {2013-09-05 20:12:42 +0000},
414 Journal = {J. Chem. Phys.},
415 Number = {11},
416 Pages = {4353-4357},
417 Title = {Rotational Friction Coefficients for Spheroids with the Slipping Boundary Condition},
418 Volume = {60},
419 Year = {1974}}
420
421 @article{hartland2011,
422 Author = {Hartland, Gregory V.},
423 Date-Added = {2013-02-11 22:54:29 +0000},
424 Date-Modified = {2013-02-18 17:56:29 +0000},
425 Journal = {Chem. Rev.},
426 Pages = {3858-3887},
427 Title = {Optical Studies of Dynamics in Noble Metal Nanostructures},
428 Volume = {11},
429 Year = {2011}}
430
431 @article{hase:2010,
432 Abstract = {Model non-equilibrium molecular dynamics (MD) simulations are presented of heat transfer from a hot Au {111} substrate to an alkylthiolate self-assembled monolayer (H-SAM) to assist in obtaining an atomic-level understanding of experiments by Wang et al. (Z. Wang{,} J. A. Carter{,} A. Lagutchev{,} Y. K. Koh{,} N.-H. Seong{,} D. G. Cahill{,} and D. D. Dlott{,} Science{,} 2007{,} 317{,} 787). Different models are considered to determine how they affect the heat transfer dynamics. They include temperature equilibrated (TE) and temperature gradient (TG) thermostat models for the Au(s) surface{,} and soft and stiff S/Au(s) models for bonding of the S-atoms to the Au(s) surface. A detailed analysis of the non-equilibrium heat transfer at the heterogeneous interface is presented. There is a short time temperature gradient within the top layers of the Au(s) surface. The S-atoms heat rapidly{,} much faster than do the C-atoms in the alkylthiolate chains. A high thermal conductivity in the H-SAM{,} perpendicular to the interface{,} results in nearly identical temperatures for the CH2 and CH3 groups versus time. Thermal-induced disorder is analyzed for the Au(s) substrate{,} the S/Au(s) interface and the H-SAM. Before heat transfer occurs from the hot Au(s) substrate to the H-SAM{,} there is disorder at the S/Au(s) interface and within the alkylthiolate chains arising from heat-induced disorder near the surface of hot Au(s). The short-time rapid heating of the S-atoms enhances this disorder. The increasing disorder of H-SAM chains with time results from both disorder at the Au/S interface and heat transfer to the H-SAM chains.},
433 Author = {Zhang, Yue and Barnes, George L. and Yan, Tianying and Hase, William L.},
434 Date-Added = {2012-12-25 17:47:40 +0000},
435 Date-Modified = {2012-12-25 17:47:40 +0000},
436 Doi = {10.1039/B923858C},
437 Issue = {17},
438 Journal = {Phys. Chem. Chem. Phys.},
439 Pages = {4435-4445},
440 Publisher = {The Royal Society of Chemistry},
441 Title = {Model Non-Equilibrium Molecular Dynamics Simulations of Heat Transfer from a Hot Gold Surface to an Alkylthiolate Self-Assembled Monolayer},
442 Url = {http://dx.doi.org/10.1039/B923858C},
443 Volume = {12},
444 Year = {2010},
445 Bdsk-Url-1 = {http://dx.doi.org/10.1039/B923858C}}
446
447 @article{hase:2011,
448 Abstract = { In a previous article (Phys. Chem. Chem. Phys.2010, 12, 4435), nonequilibrium molecular dynamics (MD) simulations of heat transfer from a hot Au{111} substrate to an alkylthiolate self-assembled monolayer (H-SAM) were presented. The simulations were performed for an H-SAM chain length of eight carbon atoms, and a qualitative agreement with the experiments of Wang et al. (Science2007, 317, 787) was found. Here, simulation results are presented for heat transfer to H-SAM surfaces with carbon chain lengths of 10--20 carbon atoms. Relaxation times for heat transfer are extracted, compared with experiment, and a qualitative agreement is obtained. The same relaxation time is found from either the temperature of the H-SAM or the orientational disorder of the H-SAM versus time. For a simulation model with the Au substrate thermally equilibrated, the relaxation times determined from the simulations are approximately a factor of 4 larger than the experimental values. },
449 Author = {Manikandan, Paranjothy and Carter, Jeffrey A. and Dlott, Dana D. and Hase, William L.},
450 Date-Added = {2012-12-25 17:47:40 +0000},
451 Date-Modified = {2013-02-18 17:57:24 +0000},
452 Doi = {10.1021/jp200672e},
453 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/jp200672e},
454 Journal = {J. Phys. Chem. C},
455 Number = {19},
456 Pages = {9622-9628},
457 Title = {Effect of Carbon Chain Length on the Dynamics of Heat Transfer at a Gold/Hydrocarbon Interface: Comparison of Simulation with Experiment},
458 Url = {http://pubs.acs.org/doi/abs/10.1021/jp200672e},
459 Volume = {115},
460 Year = {2011},
461 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/jp200672e},
462 Bdsk-Url-2 = {http://dx.doi.org/10.1021/jp200672e}}
463
464 @article{RevModPhys.61.605,
465 Author = {Swartz, E. T. and Pohl, R. O.},
466 Date-Added = {2012-12-21 20:34:12 +0000},
467 Date-Modified = {2012-12-21 20:34:12 +0000},
468 Doi = {10.1103/RevModPhys.61.605},
469 Issue = {3},
470 Journal = {Rev. Mod. Phys.},
471 Month = {Jul},
472 Pages = {605--668},
473 Publisher = {American Physical Society},
474 Title = {Thermal Boundary Resistance},
475 Url = {http://link.aps.org/doi/10.1103/RevModPhys.61.605},
476 Volume = {61},
477 Year = {1989},
478 Bdsk-Url-1 = {http://link.aps.org/doi/10.1103/RevModPhys.61.605},
479 Bdsk-Url-2 = {http://dx.doi.org/10.1103/RevModPhys.61.605}}
480
481 @article{packmol,
482 Author = {L. Mart\'{\i}nez and R. Andrade and Ernesto G. Birgin and Jos{\'e} Mario Mart\'{\i}nez},
483 Bibsource = {DBLP, http://dblp.uni-trier.de},
484 Date-Added = {2011-02-01 15:13:02 -0500},
485 Date-Modified = {2013-02-18 18:01:34 +0000},
486 Ee = {http://dx.doi.org/10.1002/jcc.21224},
487 Journal = {J. Comput. Chem.},
488 Number = {13},
489 Pages = {2157-2164},
490 Title = {PACKMOL: A Package for Building Initial Configurations for Molecular Dynamics Simulations},
491 Volume = {30},
492 Year = {2009}}
493
494 @article{doi:10.1021/jp034405s,
495 Abstract = { We use the universal force field (UFF) developed by Rapp{\'e} et al. (Rapp{\'e}, A. K.; Casewit, C. J.; Colwell, K. S.; Goddard, W. A.; Skiff, W. M. J. Am. Chem. Soc. 1992, 114, 10024) and the specific classical potentials developed from ab initio calculations for Au−benzenedithiol (BDT) molecule interaction to perform molecular dynamics (MD) simulations of a BDT monolayer on an extended Au(111) surface. The simulation system consists of 100 BDT molecules and three rigid Au layers in a simulation box that is rhombic in the plane of the Au surface. A multiple time scale algorithm, the double-reversible reference system propagator algorithm (double RESPA) based on the Nos{\'e}−Hoover dynamics scheme, and the Ewald summation with a boundary correction term for the treatment of long-range electrostatic interactions in a 2-D slab have been incorporated into the simulation technique. We investigate the local bonding properties of Au−BDT contacts and molecular orientation distributions of BDT molecules. These results show that whereas different basis sets from ab initio calculations may generate different local bonding geometric parameters (the bond length, etc.) the packing structures of BDT molecules maintain approximately the same well-ordered herringbone structure with small peak differences in the probability distributions of global geometric parameters. The methodology developed here opens an avenue for classical simulations of a metal−molecule−metal complex in molecular electronics devices. },
496 Author = {Leng, Y. and Keffer, David J. and Cummings, Peter T.},
497 Date-Added = {2012-12-17 18:38:38 +0000},
498 Date-Modified = {2012-12-17 18:38:38 +0000},
499 Doi = {10.1021/jp034405s},
500 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/jp034405s},
501 Journal = {J. Phys. Chem. B},
502 Number = {43},
503 Pages = {11940-11950},
504 Title = {Structure and Dynamics of a Benzenedithiol Monolayer on a Au(111) Surface},
505 Url = {http://pubs.acs.org/doi/abs/10.1021/jp034405s},
506 Volume = {107},
507 Year = {2003},
508 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/jp034405s},
509 Bdsk-Url-2 = {http://dx.doi.org/10.1021/jp034405s}}
510
511 @article{hautman:4994,
512 Author = {Joseph Hautman and Michael L. Klein},
513 Date-Added = {2012-12-17 18:38:26 +0000},
514 Date-Modified = {2012-12-17 18:38:26 +0000},
515 Doi = {10.1063/1.457621},
516 Journal = {J. Chem. Phys.},
517 Keywords = {MOLECULAR DYNAMICS CALCULATIONS; SIMULATION; MONOLAYERS; THIOLS; ALKYL COMPOUNDS; CHAINS; SURFACE STRUCTURE; GOLD; SUBSTRATES; CHEMISORPTION; SURFACE PROPERTIES},
518 Number = {8},
519 Pages = {4994-5001},
520 Publisher = {AIP},
521 Title = {Simulation of a Monolayer of Alkyl Thiol Chains},
522 Url = {http://link.aip.org/link/?JCP/91/4994/1},
523 Volume = {91},
524 Year = {1989},
525 Bdsk-Url-1 = {http://link.aip.org/link/?JCP/91/4994/1},
526 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.457621}}
527
528 @article{vlugt:cpc2007154,
529 Author = {Philipp Schapotschnikow and Ren{\'e} Pool and Thijs J.H. Vlugt},
530 Date-Added = {2012-12-17 18:38:20 +0000},
531 Date-Modified = {2013-02-18 18:04:43 +0000},
532 Doi = {DOI: 10.1016/j.cpc.2007.02.028},
533 Issn = {0010-4655},
534 Journal = {Comput. Phys. Commun.},
535 Keywords = {Gold nanocrystals},
536 Note = {Proceedings of the Conference on Computational Physics 2006: CCP 2006 - Conference on Computational Physics 2006},
537 Number = {1-2},
538 Pages = {154 - 157},
539 Title = {Selective Adsorption of Alkyl Thiols on Gold in Different Geometries},
540 Url = {http://www.sciencedirect.com/science/article/B6TJ5-4N3WYP0-1/2/66dbe8892f456c230b9b8fcd9c23f456},
541 Volume = {177},
542 Year = {2007},
543 Bdsk-Url-1 = {http://www.sciencedirect.com/science/article/B6TJ5-4N3WYP0-1/2/66dbe8892f456c230b9b8fcd9c23f456},
544 Bdsk-Url-2 = {http://dx.doi.org/10.1016/j.cpc.2007.02.028}}
545
546 @article{landman:1998,
547 Abstract = { Equilibrium structures and thermodynamic properties of dodecanethiol self-assembled monolayers on small (Au140) and larger (Au1289) gold nanocrystallites were investigated with the use of molecular dynamics simulations. Compact passivating monolayers are formed on the (111) and (100) facets of the nanocrystallites, with adsorption site geometries differing from those found on extended flat Au(111) and Au(100) surfaces, as well as with higher packing densities. At lower temperatures the passivating molecules organize into preferentially oriented molecular bundles with the molecules in the bundles aligned approximately parallel to each other. Thermal disordering starts at T ≳200 K, initiating at the boundaries of the bundles and involving generation of intramolecular conformational (gauche) defects which occur first at bonds near the chains' outer terminus and propagate inward toward the underlying gold nanocrystalline surface as the temperature is increased. The disordering process culminates in melting of the molecular bundles, resulting in a uniform orientational distribution of the molecules around the gold nanocrystallites. From the inflection points in the calculated caloric curves, melting temperatures were determined as 280 and 294 K for the monolayers adsorbed on the smaller and larger gold nanocrystallites, respectively. These temperatures are significantly lower than the melting temperature estimated for a self-assembled monolayer of dodecanethiol adsorbed on an extended Au(111) surface. The theoretically predicted disordering mechanisms and melting scenario, resulting in a temperature-broadened transition, support recent experimental investigations. },
548 Author = {Luedtke, W. D. and Landman, Uzi},
549 Date-Added = {2012-12-17 18:38:13 +0000},
550 Date-Modified = {2012-12-17 18:38:13 +0000},
551 Doi = {10.1021/jp981745i},
552 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/jp981745i},
553 Journal = {J. Phys. Chem. B},
554 Number = {34},
555 Pages = {6566-6572},
556 Title = {Structure and Thermodynamics of Self-Assembled Monolayers on Gold Nanocrystallites},
557 Url = {http://pubs.acs.org/doi/abs/10.1021/jp981745i},
558 Volume = {102},
559 Year = {1998},
560 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/jp981745i},
561 Bdsk-Url-2 = {http://dx.doi.org/10.1021/jp981745i}}
562
563 @article{PhysRevLett.96.186101,
564 Author = {Ge, Zhenbin and Cahill, David G. and Braun, Paul V.},
565 Date-Added = {2012-12-17 17:44:53 +0000},
566 Date-Modified = {2012-12-17 17:44:53 +0000},
567 Doi = {10.1103/PhysRevLett.96.186101},
568 Journal = prl,
569 Month = {May},
570 Number = {18},
571 Numpages = {4},
572 Pages = {186101},
573 Publisher = {American Physical Society},
574 Title = {Thermal Conductance of Hydrophilic and Hydrophobic Interfaces},
575 Volume = {96},
576 Year = {2006},
577 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRevLett.96.186101}}
578
579 @article{Larson:2007hw,
580 Abstract = {Nanoparticles which consist of a plasmonic layer and an iron oxide moiety could provide a promising platform for development of multimodal imaging and therapy approaches in future medicine. However, the feasibility of this platform has yet to be fully explored. In this study we demonstrated the use of gold-coated iron oxide hybrid nanoparticles for combined molecular specific MRI/optical imaging and photothermal therapy of cancer cells. The gold layer exhibits a surface plasmon resonance that provides optical contrast due to light scattering in the visible region and also presents a convenient surface for conjugating targeting moieties, while the iron oxide cores give strong T-2 (spin-spin relaxation time) contrast. The strong optical absorption of the plasmonic gold layer also makes these nanoparticles a promising agent for photothermal therapy. We synthesized hybrid nanoparticles which specifically target epidermal growth factor receptor (EGFR), a common biomarker for many epithelial cancers. We demonstrated molecular specific MRI and optical imaging in MDA-MB-468 breast cancer cells. Furthermore, we showed that receptor-mediated aggregation of anti-EGFR hybrid nanoparticles allows selective destruction of highly proliferative cancer cells using a nanosecond pulsed laser at 700 nm wavelength, a significant shift from the peak absorbance of isolated hybrid nanoparticles at 532 nm.},
581 Address = {DIRAC HOUSE, TEMPLE BACK, BRISTOL BS1 6BE, ENGLAND},
582 Author = {Larson, Timothy A. and Bankson, James and Aaron, Jesse and Sokolov, Konstantin},
583 Date = {AUG 15 2007},
584 Date-Added = {2012-12-17 17:44:44 +0000},
585 Date-Modified = {2013-02-18 17:34:30 +0000},
586 Doi = {ARTN 325101},
587 Journal = {Nanotechnology},
588 Pages = {325101},
589 Publisher = {IOP PUBLISHING LTD},
590 Timescited = {5},
591 Title = {Hybrid Plasmonic Magnetic Nanoparticles as Molecular Specific Agents for MRI/Optical Imaging and Photothermal Therapy of Cancer Cells},
592 Volume = {18},
593 Year = {2007},
594 Bdsk-Url-1 = {http://dx.doi.org/325101}}
595
596 @article{Huff:2007ye,
597 Abstract = {Plasmon-resonant gold nanorods, which have large absorption cross sections at near-infrared frequencies, are excellent candidates as multifunctional agents for image-guided therapies based on localized hyperthermia. The controlled modification of the surface chemistry of the nanorods is of critical importance, as issues of cell-specific targeting and nonspecific uptake must be addressed prior to clinical evaluation. Nanorods coated with cetyltrimethylammonium bromide (a cationic surfactant used in nanorod synthesis) are internalized within hours into KB cells by a nonspecific uptake pathway, whereas the careful removal of cetyltrimethylammonium bromide from nanorods functionalized with folate results in their accumulation on the cell surface over the same time interval. In either case, the nanorods render the tumor cells highly susceptible to photothermal damage when irradiated at the nanorods' longitudinal plasmon resonance, generating extensive blebbing of the cell membrane at laser fluences as low as 30 J/cm(2).},
598 Address = {UNITEC HOUSE, 3RD FLOOR, 2 ALBERT PLACE, FINCHLEY CENTRAL, LONDON, N3 1QB, ENGLAND},
599 Author = {Huff, Terry B. and Tong, Ling and Zhao, Yan and Hansen, Matthew N. and Cheng, Ji-Xin and Wei, Alexander},
600 Date = {FEB 2007},
601 Date-Added = {2012-12-17 17:44:36 +0000},
602 Date-Modified = {2012-12-17 17:44:36 +0000},
603 Doi = {DOI 10.2217/17435889.2.1.125},
604 Journal = {Nanomedicine},
605 Keywords = {folate receptor; hyperthermia; imaging; nanorods; nonlinear optical microscopy; plasmon resonance; targeted therapy},
606 Pages = {125-132},
607 Publisher = {FUTURE MEDICINE LTD},
608 Timescited = {13},
609 Title = {Hyperthermic Effects of Gold Nanorods on Tumor Cells},
610 Volume = {2},
611 Year = {2007},
612 Bdsk-Url-1 = {http://dx.doi.org/10.2217/17435889.2.1.125}}
613
614 @article{Jiang:2008hc,
615 Abstract = {Abstract: Nonequilibrium molecular dynamics simulations with the nonpolarizable SPC/E (Berendsen et al., J. Phys. Chem. 1987, 91, 6269) and the polarizable COS/G2 (Yu and van Gunsteren, J. Chem. Phys. 2004, 121, 9549) force fields have been employed to calculate the thermal conductivity and other associated properties of methane hydrate over a temperature range from 30 to 260 K. The calculated results are compared to experimental data over this same range. The values of the thermal conductivity calculated with the COS/G2 model are closer to the experimental values than are those calculated with the nonpolarizable SPC/E model. The calculations match the temperature trend in the experimental data at temperatures below 50 K; however, they exhibit a slight decrease in thermal conductivity at higher temperatures in comparison to an opposite trend in the experimental data. The calculated thermal conductivity values are found to be relatively insensitive to the occupancy of the cages except at low (T d 50 K) temperatures, which indicates that the differences between the two lattice structures may have a more dominant role than generally thought in explaining the low thermal conductivity of methane hydrate compared to ice Ih. The introduction of defects into the water lattice is found to cause a reduction in the thermal conductivity but to have a negligible impact on its temperature dependence.},
616 Affiliation = {National Energy Technology Laboratory, U.S. Department of Energy, Post Office Box 10940, Pittsburgh, Pennsylvania 15236, Department of Chemistry and Center for Molecular and Materials Simulations, University of Pittsburgh, Pittsburgh, Pennsylvania 15260, and Parsons Project Services, Inc., South Park, Pennsylvania 15129},
617 Author = {Jiang, Hao and Myshakin, Evgeniy M. and Jordan, Kenneth D. and Warzinski, Robert P.},
618 Date-Added = {2012-12-17 16:57:19 +0000},
619 Date-Modified = {2014-03-13 14:15:48 +0000},
620 Doi = {10.1021/jp802942v},
621 Issn = {1520-6106},
622 Journal = jpcb,
623 Pages = {10207-10216},
624 Title = {Molecular Dynamics Simulations of the Thermal Conductivity of Methane Hydrate},
625 Volume = {112},
626 Year = {2008},
627 Bdsk-Url-1 = {http://pubs3.acs.org/acs/journals/doilookup?in_doi=10.1021/jp802942v}}
628
629 @article{Schelling:2002dp,
630 Author = {Schelling, P. K. and Phillpot, S. R. and Keblinski, P.},
631 Date = {APR 1 2002},
632 Date-Added = {2012-12-17 16:57:10 +0000},
633 Date-Modified = {2014-03-13 14:15:48 +0000},
634 Doi = {10.1103/PhysRevB.65.144306},
635 Isi = {WOS:000174980300055},
636 Issn = {1098-0121},
637 Journal = prb,
638 Month = {Apr},
639 Number = {14},
640 Pages = {144306},
641 Publication-Type = {J},
642 Times-Cited = {288},
643 Title = {Comparison of Atomic-Level Simulation Methods for Computing Thermal Conductivity},
644 Volume = {65},
645 Year = {2002},
646 Z8 = {12},
647 Z9 = {296},
648 Zb = {0},
649 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRevB.65.144306}}
650
651 @article{Evans:2002tg,
652 Author = {Evans, D. J. and Searles, D. J.},
653 Date = {NOV 2002},
654 Date-Added = {2012-12-17 16:56:59 +0000},
655 Date-Modified = {2014-03-13 14:15:48 +0000},
656 Doi = {10.1080/00018730210155133},
657 Isi = {WOS:000179448200001},
658 Issn = {0001-8732},
659 Journal = {Adv. Phys.},
660 Month = {Nov},
661 Number = {7},
662 Pages = {1529--1585},
663 Publication-Type = {J},
664 Times-Cited = {309},
665 Title = {The Fluctuation Theorem},
666 Volume = {51},
667 Year = {2002},
668 Z8 = {3},
669 Z9 = {311},
670 Zb = {9},
671 Bdsk-Url-1 = {http://dx.doi.org/10.1080/00018730210155133}}
672
673 @article{Berthier:2002ai,
674 Author = {Berthier, L. and Barrat, J. L.},
675 Date = {APR 8 2002},
676 Date-Added = {2012-12-17 16:56:47 +0000},
677 Date-Modified = {2014-03-13 14:15:48 +0000},
678 Doi = {10.1063/1.1460862},
679 Isi = {WOS:000174634200036},
680 Issn = {0021-9606},
681 Journal = jcp,
682 Month = {Apr},
683 Number = {14},
684 Pages = {6228--6242},
685 Publication-Type = {J},
686 Times-Cited = {172},
687 Title = {Nonequilibrium Dynamics and Fluctuation-Dissipation Relation in a Sheared Fluid},
688 Volume = {116},
689 Year = {2002},
690 Z8 = {0},
691 Z9 = {172},
692 Zb = {1},
693 Bdsk-Url-1 = {http://dx.doi.org/10.1063/1.1460862}}
694
695 @article{Maginn:1993kl,
696 Author = {Maginn, E. J. and Bell, A. T. and Theodorou, D. N.},
697 Date = {APR 22 1993},
698 Date-Added = {2012-12-17 16:56:40 +0000},
699 Date-Modified = {2014-03-13 14:15:48 +0000},
700 Doi = {10.1021/j100118a038},
701 Isi = {WOS:A1993KY46600039},
702 Issn = {0022-3654},
703 Journal = jpc,
704 Month = {Apr},
705 Number = {16},
706 Pages = {4173--4181},
707 Publication-Type = {J},
708 Times-Cited = {198},
709 Title = {Transport Diffusivity of Methane in Silicalite from Equilibrium and Nonequilibrium Simulations},
710 Volume = {97},
711 Year = {1993},
712 Z8 = {4},
713 Z9 = {201},
714 Zb = {0},
715 Bdsk-Url-1 = {http://dx.doi.org/10.1021/j100118a038}}
716
717 @article{Erpenbeck:1984qe,
718 Author = {Erpenbeck, J. J.},
719 Date = {1984},
720 Date-Added = {2012-12-17 16:56:32 +0000},
721 Date-Modified = {2014-03-13 14:15:48 +0000},
722 Doi = {10.1103/PhysRevLett.52.1333},
723 Isi = {WOS:A1984SK96700021},
724 Issn = {0031-9007},
725 Journal = prl,
726 Number = {15},
727 Pages = {1333--1335},
728 Publication-Type = {J},
729 Times-Cited = {189},
730 Title = {Shear Viscosity of the Hard-Sphere Fluid via Nonequilibrium Molecular Dynamics},
731 Volume = {52},
732 Year = {1984},
733 Z8 = {0},
734 Z9 = {189},
735 Zb = {1},
736 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRevLett.52.1333}}
737
738 @article{Evans:1982oq,
739 Author = {Evans, Denis J.},
740 Date-Added = {2012-12-17 16:56:24 +0000},
741 Date-Modified = {2014-03-13 14:15:48 +0000},
742 Journal = {Phys. Lett. A},
743 Number = {9},
744 Pages = {457--460},
745 Title = {Homogeneous NEMD Algorithm for Thermal Conductivity -- Application of Non-Canonical Linear Response Theory},
746 Ty = {JOUR},
747 Url = {http://www.sciencedirect.com/science/article/B6TVM-46SXM58-S0/1/b270d693318250f3ed0dbce1a535ea50},
748 Volume = {91},
749 Year = {1982},
750 Bdsk-Url-1 = {http://www.sciencedirect.com/science/article/B6TVM-46SXM58-S0/1/b270d693318250f3ed0dbce1a535ea50}}
751
752 @article{Ashurst:1975eu,
753 Author = {Ashurst, W. T. and Hoover, W. G.},
754 Date = {1975},
755 Date-Added = {2012-12-17 16:56:05 +0000},
756 Date-Modified = {2014-03-13 14:15:48 +0000},
757 Doi = {10.1103/PhysRevA.11.658},
758 Isi = {WOS:A1975V548400036},
759 Issn = {1050-2947},
760 Journal = pra,
761 Number = {2},
762 Pages = {658--678},
763 Publication-Type = {J},
764 Times-Cited = {295},
765 Title = {Dense-Fluid Shear Viscosity via Nonequilibrium Molecular Dynamics},
766 Volume = {11},
767 Year = {1975},
768 Z8 = {3},
769 Z9 = {298},
770 Zb = {1},
771 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRevA.11.658}}
772
773 @article{kinaci:014106,
774 Author = {A. Kinaci and J. B. Haskins and T. \c{C}a\u{g}in},
775 Date-Added = {2012-12-17 16:55:56 +0000},
776 Date-Modified = {2012-12-17 16:55:56 +0000},
777 Doi = {10.1063/1.4731450},
778 Eid = {014106},
779 Journal = jcp,
780 Keywords = {argon; elemental semiconductors; Ge-Si alloys; molecular dynamics method; nanostructured materials; porous semiconductors; silicon; thermal conductivity},
781 Number = {1},
782 Numpages = {8},
783 Pages = {014106},
784 Publisher = {AIP},
785 Title = {On Calculation of Thermal Conductivity from Einstein Relation in Equilibrium Molecular Dynamics},
786 Url = {http://link.aip.org/link/?JCP/137/014106/1},
787 Volume = {137},
788 Year = {2012},
789 Bdsk-Url-1 = {http://link.aip.org/link/?JCP/137/014106/1},
790 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.4731450}}
791
792 @article{che:6888,
793 Author = {Jianwei Che and Tahir Cagin and Weiqiao Deng and William A. Goddard III},
794 Date-Added = {2012-12-17 16:55:48 +0000},
795 Date-Modified = {2012-12-17 16:55:48 +0000},
796 Doi = {10.1063/1.1310223},
797 Journal = jcp,
798 Keywords = {diamond; thermal conductivity; digital simulation; vacancies (crystal); Green's function methods; isotope effects},
799 Number = {16},
800 Pages = {6888-6900},
801 Publisher = {AIP},
802 Title = {Thermal Conductivity of Diamond and Related Materials from Molecular Dynamics Simulations},
803 Url = {http://link.aip.org/link/?JCP/113/6888/1},
804 Volume = {113},
805 Year = {2000},
806 Bdsk-Url-1 = {http://link.aip.org/link/?JCP/113/6888/1},
807 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.1310223}}
808
809 @article{Viscardy:2007rp,
810 Abstract = {The thermal conductivity is calculated with the Helfand-moment method in the Lennard-Jones fluid near the triple point. The Helfand moment of thermal conductivity is here derived for molecular dynamics with periodic boundary conditions. Thermal conductivity is given by a generalized Einstein relation with this Helfand moment. The authors compute thermal conductivity by this new method and compare it with their own values obtained by the standard Green-Kubo method. The agreement is excellent. (C) 2007 American Institute of Physics.},
811 Address = {CIRCULATION \& FULFILLMENT DIV, 2 HUNTINGTON QUADRANGLE, STE 1 N O 1, MELVILLE, NY 11747-4501 USA},
812 Author = {Viscardy, S. and Servantie, J. and Gaspard, P.},
813 Date = {MAY 14 2007},
814 Date-Added = {2012-12-17 16:55:32 +0000},
815 Date-Modified = {2013-02-18 17:58:40 +0000},
816 Doi = {ARTN 184513},
817 Journal = jcp,
818 Pages = {184513},
819 Publisher = {AMER INST PHYSICS},
820 Timescited = {1},
821 Title = {Transport and Helfand Moments in the Lennard-Jones Fluid. II. Thermal Conductivity},
822 Volume = {126},
823 Year = {2007},
824 Bdsk-Url-1 = {http://dx.doi.org/184513}}
825
826 @article{PhysRev.119.1,
827 Author = {Helfand, Eugene},
828 Date-Added = {2012-12-17 16:55:19 +0000},
829 Date-Modified = {2012-12-17 16:55:19 +0000},
830 Doi = {10.1103/PhysRev.119.1},
831 Journal = {Phys. Rev.},
832 Month = {Jul},
833 Number = {1},
834 Numpages = {8},
835 Pages = {1--9},
836 Publisher = {American Physical Society},
837 Title = {Transport Coefficients from Dissipation in a Canonical Ensemble},
838 Volume = {119},
839 Year = {1960},
840 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRev.119.1}}
841
842 @article{Evans:1986nx,
843 Author = {Evans, Denis J.},
844 Date-Added = {2012-12-17 16:55:19 +0000},
845 Date-Modified = {2014-03-13 14:15:48 +0000},
846 Doi = {10.1103/PhysRevA.34.1449},
847 Journal = {Phys. Rev. A},
848 Month = {Aug},
849 Number = {2},
850 Numpages = {4},
851 Pages = {1449--1453},
852 Publisher = {American Physical Society},
853 Title = {Thermal Conductivity of the Lennard-Jones Fluid},
854 Volume = {34},
855 Year = {1986},
856 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRevA.34.1449}}
857
858 @article{MASSOBRIO:1984bl,
859 Address = {ONE PHYSICS ELLIPSE, COLLEGE PK, MD 20740-3844 USA},
860 Author = {Massobrio, C and Ciccotti, G},
861 Date = {1984},
862 Date-Added = {2012-12-17 16:55:03 +0000},
863 Date-Modified = {2012-12-21 22:42:02 +0000},
864 Journal = pra,
865 Pages = {3191-3197},
866 Publisher = {AMERICAN PHYSICAL SOC},
867 Timescited = {29},
868 Title = {Lennard-Jones Triple-Point Conductivity via Weak External Fields},
869 Volume = {30},
870 Year = {1984}}
871
872 @article{PhysRevB.37.5677,
873 Author = {Heyes, David M.},
874 Date-Added = {2012-12-17 16:54:55 +0000},
875 Date-Modified = {2012-12-17 16:54:55 +0000},
876 Doi = {10.1103/PhysRevB.37.5677},
877 Journal = prb,
878 Month = {Apr},
879 Number = {10},
880 Numpages = {19},
881 Pages = {5677--5696},
882 Publisher = {American Physical Society},
883 Title = {Transport Coefficients of Lennard-Jones Fluids: A Molecular-Dynamics and Effective-Hard-Sphere Treatment},
884 Volume = {37},
885 Year = {1988},
886 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRevB.37.5677}}
887
888 @article{PhysRevB.80.195406,
889 Author = {Juv\'e, Vincent and Scardamaglia, Mattia and Maioli, Paolo and Crut, Aur\'elien and Merabia, Samy and Joly, Laurent and Del Fatti, Natalia and Vall\'ee, Fabrice},
890 Date-Added = {2012-12-17 16:54:55 +0000},
891 Date-Modified = {2012-12-17 16:54:55 +0000},
892 Doi = {10.1103/PhysRevB.80.195406},
893 Journal = prb,
894 Month = {Nov},
895 Number = {19},
896 Numpages = {6},
897 Pages = {195406},
898 Publisher = {American Physical Society},
899 Title = {Cooling Dynamics and Thermal Interface Resistance of Glass-Embedded Metal Nanoparticles},
900 Volume = {80},
901 Year = {2009},
902 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRevB.80.195406}}
903
904 @article{Wang10082007,
905 Abstract = {At the level of individual molecules, familiar concepts of heat transport no longer apply. When large amounts of heat are transported through a molecule, a crucial process in molecular electronic devices, energy is carried by discrete molecular vibrational excitations. We studied heat transport through self-assembled monolayers of long-chain hydrocarbon molecules anchored to a gold substrate by ultrafast heating of the gold with a femtosecond laser pulse. When the heat reached the methyl groups at the chain ends, a nonlinear coherent vibrational spectroscopy technique detected the resulting thermally induced disorder. The flow of heat into the chains was limited by the interface conductance. The leading edge of the heat burst traveled ballistically along the chains at a velocity of 1 kilometer per second. The molecular conductance per chain was 50 picowatts per kelvin.},
906 Author = {Wang, Zhaohui and Carter, Jeffrey A. and Lagutchev, Alexei and Koh, Yee Kan and Seong, Nak-Hyun and Cahill, David G. and Dlott, Dana D.},
907 Date-Added = {2012-12-17 16:54:31 +0000},
908 Date-Modified = {2012-12-17 16:54:31 +0000},
909 Doi = {10.1126/science.1145220},
910 Eprint = {http://www.sciencemag.org/content/317/5839/787.full.pdf},
911 Journal = {Science},
912 Number = {5839},
913 Pages = {787-790},
914 Title = {Ultrafast Flash Thermal Conductance of Molecular Chains},
915 Url = {http://www.sciencemag.org/content/317/5839/787.abstract},
916 Volume = {317},
917 Year = {2007},
918 Bdsk-Url-1 = {http://www.sciencemag.org/content/317/5839/787.abstract},
919 Bdsk-Url-2 = {http://dx.doi.org/10.1126/science.1145220}}
920
921 @article{doi:10.1021/la904855s,
922 Annote = {PMID: 20166728},
923 Author = {Alper, Joshua and Hamad-Schifferli, Kimberly},
924 Date-Added = {2012-12-17 16:54:12 +0000},
925 Date-Modified = {2013-02-18 17:57:03 +0000},
926 Doi = {10.1021/la904855s},
927 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/la904855s},
928 Journal = {Langmuir},
929 Number = {6},
930 Pages = {3786-3789},
931 Title = {Effect of Ligands on Thermal Dissipation from Gold Nanorods},
932 Url = {http://pubs.acs.org/doi/abs/10.1021/la904855s},
933 Volume = {26},
934 Year = {2010},
935 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/la904855s},
936 Bdsk-Url-2 = {http://dx.doi.org/10.1021/la904855s}}
937
938 @article{doi:10.1021/jp048375k,
939 Abstract = { Water- and alcohol-soluble AuPd nanoparticles have been investigated to determine the effect of the organic stabilizing group on the thermal conductance G of the particle/fluid interface. The thermal decays of tiopronin-stabilized 3−5-nm diameter AuPd alloy nanoparticles, thioalkylated ethylene glycol-stabilized 3−5-nm diameter AuPd nanoparticles, and cetyltrimethylammonium bromide-stabilized 22-nm diameter Au-core/AuPd-shell nanoparticles give thermal conductances G ≈ 100−300 MW m-2 K-1 for the particle/water interfaces, approximately an order of magnitude larger than the conductance of the interfaces between alkanethiol-terminated AuPd nanoparticles and toluene. The similar values of G for particles ranging in size from 3 to 24 nm with widely varying surface chemistry indicate that the thermal coupling between AuPd nanoparticles and water is strong regardless of the self-assembled stabilizing group. },
940 Author = {Ge, Zhenbin and Cahill, David G. and Braun, Paul V.},
941 Date-Added = {2012-12-17 16:54:03 +0000},
942 Date-Modified = {2012-12-17 16:54:03 +0000},
943 Doi = {10.1021/jp048375k},
944 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/jp048375k},
945 Journal = jpcb,
946 Number = {49},
947 Pages = {18870-18875},
948 Title = {AuPd Metal Nanoparticles as Probes of Nanoscale Thermal Transport in Aqueous Solution},
949 Url = {http://pubs.acs.org/doi/abs/10.1021/jp048375k},
950 Volume = {108},
951 Year = {2004},
952 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/jp048375k},
953 Bdsk-Url-2 = {http://dx.doi.org/10.1021/jp048375k}}
954
955 @article{doi:10.1021/jp8051888,
956 Abstract = { Thermal transport between CTAB passivated gold nanorods and solvent is studied by an optical pump−probe technique. Increasing the free CTAB concentration from 1 mM to 10 mM causes a ∼3× increase in the CTAB layer's effective thermal interface conductance and a corresponding shift in the longitudinal surface plasmon resonance. The transition occurs near the CTAB critical micelle concentration, revealing the importance of the role of free ligand on thermal transport. },
957 Author = {Schmidt, Aaron J. and Alper, Joshua D. and Chiesa, Matteo and Chen, Gang and Das, Sarit K. and Hamad-Schifferli, Kimberly},
958 Date-Added = {2012-12-17 16:54:03 +0000},
959 Date-Modified = {2013-02-18 17:54:59 +0000},
960 Doi = {10.1021/jp8051888},
961 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/jp8051888},
962 Journal = jpcc,
963 Number = {35},
964 Pages = {13320-13323},
965 Title = {Probing the Gold Nanorod-Ligand-Solvent Interface by Plasmonic Absorption and Thermal Decay},
966 Url = {http://pubs.acs.org/doi/abs/10.1021/jp8051888},
967 Volume = {112},
968 Year = {2008},
969 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/jp8051888},
970 Bdsk-Url-2 = {http://dx.doi.org/10.1021/jp8051888}}
971
972 @article{PhysRevB.67.054302,
973 Author = {Costescu, Ruxandra M. and Wall, Marcel A. and Cahill, David G.},
974 Date-Added = {2012-12-17 16:53:48 +0000},
975 Date-Modified = {2012-12-17 16:53:48 +0000},
976 Doi = {10.1103/PhysRevB.67.054302},
977 Journal = prb,
978 Month = {Feb},
979 Number = {5},
980 Numpages = {5},
981 Pages = {054302},
982 Publisher = {American Physical Society},
983 Title = {Thermal Conductance of Epitaxial Interfaces},
984 Volume = {67},
985 Year = {2003},
986 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRevB.67.054302}}
987
988 @article{cahill:793,
989 Author = {David G. Cahill and Wayne K. Ford and Kenneth E. Goodson and Gerald D. Mahan and Arun Majumdar and Humphrey J. Maris and Roberto Merlin and Simon R. Phillpot},
990 Date-Added = {2012-12-17 16:53:36 +0000},
991 Date-Modified = {2012-12-17 16:53:36 +0000},
992 Doi = {10.1063/1.1524305},
993 Journal = {J. Appl. Phys.},
994 Keywords = {nanostructured materials; reviews; thermal conductivity; interface phenomena; molecular dynamics method; thermal management (packaging); Boltzmann equation; carbon nanotubes; porosity; semiconductor superlattices; thermoreflectance; interface phonons; thermoelectricity; phonon-phonon interactions},
995 Number = {2},
996 Pages = {793-818},
997 Publisher = {AIP},
998 Title = {Nanoscale Thermal Transport},
999 Url = {http://link.aip.org/link/?JAP/93/793/1},
1000 Volume = {93},
1001 Year = {2003},
1002 Bdsk-Url-1 = {http://link.aip.org/link/?JAP/93/793/1},
1003 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.1524305}}
1004
1005 @article{Eapen:2007mw,
1006 Abstract = {In a well-dispersed nanofluid with strong cluster-fluid attraction, thermal conduction paths can arise through percolating amorphouslike interfacial structures. This results in a thermal conductivity enhancement beyond the Maxwell limit of 3 phi, with phi being the nanoparticle volume fraction. Our findings from nonequilibrium molecular dynamics simulations, which are amenable to experimental verification, can provide a theoretical basis for the development of future nanofluids.},
1007 Address = {ONE PHYSICS ELLIPSE, COLLEGE PK, MD 20740-3844 USA},
1008 Author = {Eapen, Jacob and Li, Ju and Yip, Sidney},
1009 Date = {DEC 2007},
1010 Date-Added = {2012-12-17 16:53:30 +0000},
1011 Date-Modified = {2013-02-18 17:48:08 +0000},
1012 Doi = {ARTN 062501},
1013 Journal = pre,
1014 Pages = {062501},
1015 Publisher = {AMER PHYSICAL SOC},
1016 Timescited = {0},
1017 Title = {Beyond the Maxwell Limit: Thermal Conduction in Nanofluids with Percolating Fluid Structures},
1018 Volume = {76},
1019 Year = {2007},
1020 Bdsk-Url-1 = {http://dx.doi.org/062501}}
1021
1022 @article{Xue:2003ya,
1023 Abstract = {Using nonequilibrium molecular dynamics simulations in which a temperature gradient is imposed, we determine the thermal resistance of a model liquid-solid interface. Our simulations reveal that the strength of the bonding between liquid and solid atoms plays a key role in determining interfacial thermal resistance. Moreover, we find that the functional dependence of the thermal resistance on the strength of the liquid-solid interactions exhibits two distinct regimes: (i) exponential dependence for weak bonding (nonwetting liquid) and (ii) power law dependence for strong bonding (wetting liquid). The identification of the two regimes of the Kapitza resistance has profound implications for understanding and designing the thermal properties of nanocomposite materials. (C) 2003 American Institute of Physics.},
1024 Address = {CIRCULATION \& FULFILLMENT DIV, 2 HUNTINGTON QUADRANGLE, STE 1 N O 1, MELVILLE, NY 11747-4501 USA},
1025 Author = {Xue, L and Keblinski, P and Phillpot, SR and Choi, SUS and Eastman, JA},
1026 Date = {JAN 1 2003},
1027 Date-Added = {2012-12-17 16:53:22 +0000},
1028 Date-Modified = {2012-12-17 16:53:22 +0000},
1029 Doi = {DOI 10.1063/1.1525806},
1030 Journal = jcp,
1031 Pages = {337-339},
1032 Publisher = {AMER INST PHYSICS},
1033 Timescited = {19},
1034 Title = {Two Regimes of Thermal Resistance at a Liquid-Solid Interface},
1035 Volume = {118},
1036 Year = {2003},
1037 Bdsk-Url-1 = {http://dx.doi.org/10.1063/1.1525806}}
1038
1039 @article{Xue:2004oa,
1040 Abstract = {Using non-equilibrium molecular dynamics simulations in which a temperature gradient is imposed, we study how the ordering of the liquid at the liquid-solid interface affects the interfacial thermal resistance. Our simulations of a simple monoatomic liquid show no effect on the thermal transport either normal to the surface or parallel to the surface. Even for of a liquid that is highly confined between two solids, we find no effect on thermal conductivity. This contrasts with well-known significant effect of confinement on the viscoelastic response. Our findings suggest that the experimentally observed large enhancement of thermal conductivity in suspensions of solid nanosized particles (nanofluids) can not be explained by altered thermal transport properties of the layered liquid. (C) 2004 Elsevier Ltd. All rights reserved.},
1041 Address = {THE BOULEVARD, LANGFORD LANE, KIDLINGTON, OXFORD OX5 1GB, ENGLAND},
1042 Author = {Xue, L and Keblinski, P and Phillpot, SR and Choi, SUS and Eastman, JA},
1043 Date = {SEP 2004},
1044 Date-Added = {2012-12-17 16:53:22 +0000},
1045 Date-Modified = {2013-02-18 17:47:37 +0000},
1046 Doi = {DOI 10.1016/ijheatmasstransfer.2004.05.016},
1047 Journal = {Int. J. Heat Mass Tran.},
1048 Keywords = {interfacial Thermal Resistance; liquid-solid interface; molecular dynamics simulations; nanofluids},
1049 Pages = {4277-4284},
1050 Publisher = {PERGAMON-ELSEVIER SCIENCE LTD},
1051 Timescited = {29},
1052 Title = {Effect of Liquid Layering at the Liquid-Solid Interface on Thermal Transport},
1053 Volume = {47},
1054 Year = {2004},
1055 Bdsk-Url-1 = {http://dx.doi.org/10.1016/ijheatmasstransfer.2004.05.016}}
1056
1057 @article{Lee:1999ct,
1058 Abstract = {Oxide nanofluids were produced and their thermal conductivities were measured by a transient hot-wire method. The experimental results show that these nanofluids, containing a small amount of nanoparticles, have substantially higher thermal conductivities than the same liquids without nanoparticles. Comparisons between experiments and the Hamilton and Crosser model show that the model can predict the thermal conductivity of nanofluids containing large agglomerated Al2O3 particles. However, the model appears to be inadequate for nanofluids containing CuO particles. This suggests that not only particle shape but size is considered to be dominant in enhancing the thermal conductivity of nanofluids.},
1059 Address = {345 E 47TH ST, NEW YORK, NY 10017 USA},
1060 Author = {Lee, S and Choi, SUS and Li, S and Eastman, JA},
1061 Date = {MAY 1999},
1062 Date-Added = {2012-12-17 16:53:15 +0000},
1063 Date-Modified = {2013-02-18 17:46:57 +0000},
1064 Journal = {J. Heat Transf.},
1065 Keywords = {conduction; enhancement; heat transfer; nanoscale; two-phase},
1066 Pages = {280-289},
1067 Publisher = {ASME-AMER SOC MECHANICAL ENG},
1068 Timescited = {183},
1069 Title = {Measuring Thermal Conductivity of Fluids Containing Oxide Nanoparticles},
1070 Volume = {121},
1071 Year = {1999}}
1072
1073 @article{Keblinski:2002bx,
1074 Abstract = {Recent measurements on nanofluids have demonstrated that the thermal conductivity increases with decreasing grain size. However, Such increases cannot be explained by existing theories. We explore four possible explanations for this anomalous increase: Brownian motion of the particles, molecular-level layering of the liquid at the liquid/particle interface, the nature of heat transport in the nanoparticles. and the effects of nanoparticle clustering. We show that the key factors in understanding thermal properties of nanofluids are the ballistic, rather than diffusive, nature of heat transport in the nanoparticles, combined with direct or fluid-mediated clustering effects that provide paths for rapid heat transport. (C) 2001 Elsevier Science Ltd. All rights reserved.},
1075 Address = {THE BOULEVARD, LANGFORD LANE, KIDLINGTON, OXFORD OX5 1GB, ENGLAND},
1076 Author = {Keblinski, P and Phillpot, SR and Choi, SUS and Eastman, JA},
1077 Date = {FEB 2002},
1078 Date-Added = {2012-12-17 16:53:06 +0000},
1079 Date-Modified = {2013-02-18 17:41:04 +0000},
1080 Journal = {Int. J. Heat Mass Tran.},
1081 Keywords = {thermal conductivity; nanofluids; molecular dynamics simulations; ballistic heat transport},
1082 Pages = {855-863},
1083 Publisher = {PERGAMON-ELSEVIER SCIENCE LTD},
1084 Timescited = {161},
1085 Title = {Mechanisms of Heat Flow in Suspensions of Nano-Sized Particles (Nanofluids)},
1086 Volume = {45},
1087 Year = {2002}}
1088
1089 @article{Eastman:2001wb,
1090 Abstract = {It is shown that a "nanofluid" consisting of copper nanometer-sized particles dispersed in ethylene glycol has a much higher effective thermal conductivity than either pure ethylene glycol or ethylene glycol containing the same volume fraction of dispersed oxide nanoparticles. The effective thermal conductivity of ethylene glycol is shown to be increased by up to 40\% for a nanofluid consisting of ethylene glycol containing approximately 0.3 vol \% Cu nanoparticles of mean diameter < 10 nm. The results are anomalous based on previous theoretical calculations that had predicted a strong effect of particle shape on effective nanofluid thermal conductivity, but no effect of either particle size or particle thermal conductivity. (C) 2001 American Institute of Physics.},
1091 Address = {2 HUNTINGTON QUADRANGLE, STE 1NO1, MELVILLE, NY 11747-4501 USA},
1092 Author = {Eastman, JA and Choi, SUS and Li, S and Yu, W and Thompson, LJ},
1093 Date = {FEB 5 2001},
1094 Date-Added = {2012-12-17 16:52:55 +0000},
1095 Date-Modified = {2013-02-18 17:40:41 +0000},
1096 Journal = {Appl. Phys. Lett.},
1097 Pages = {718-720},
1098 Publisher = {AMER INST PHYSICS},
1099 Timescited = {246},
1100 Title = {Anomalously Increased Effective Thermal Conductivities of Ethylene Glycol-Based Nanofluids Containing Copper Nanoparticles},
1101 Volume = {78},
1102 Year = {2001}}
1103
1104 @article{Eapen:2007th,
1105 Abstract = {Transient hot-wire data on thermal conductivity of suspensions of silica and perfluorinated particles show agreement with the mean-field theory of Maxwell but not with the recently postulated microconvection mechanism. The influence of interfacial thermal resistance, convective effects at microscales, and the possibility of thermal conductivity enhancements beyond the Maxwell limit are discussed.},
1106 Address = {ONE PHYSICS ELLIPSE, COLLEGE PK, MD 20740-3844 USA},
1107 Author = {Eapen, Jacob and Williams, Wesley C. and Buongiorno, Jacopo and Hu, Lin-Wen and Yip, Sidney and Rusconi, Roberto and Piazza, Roberto},
1108 Date = {AUG 31 2007},
1109 Date-Added = {2012-12-17 16:52:46 +0000},
1110 Date-Modified = {2013-02-18 17:40:15 +0000},
1111 Doi = {ARTN 095901},
1112 Journal = prl,
1113 Pages = {095901},
1114 Publisher = {AMER PHYSICAL SOC},
1115 Timescited = {8},
1116 Title = {Mean-Field Versus Microconvection Effects in Nanofluid Thermal Conduction},
1117 Volume = {99},
1118 Year = {2007},
1119 Bdsk-Url-1 = {http://dx.doi.org/095901}}
1120
1121 @article{Plech:2005kx,
1122 Abstract = {The transient structural response of laser excited gold nanoparticle sols has been recorded by pulsed X-ray scattering. Time resolved wide angle and small angle scattering (SAXS) record the changes in structure both of the nanoparticles and the water environment subsequent to femtosecond laser excitation. Within the first nanosecond after the excitation of the nanoparticles, the water phase shows a signature of compression, induced by a heat-induced evaporation of the water shell close to the heated nanoparticles. The particles themselves undergo a melting transition and are fragmented to Form new clusters in the nanometer range. (C) 2004 Elsevier B.V. All rights reserved.},
1123 Author = {Plech, A and Kotaidis, V and Lorenc, M and Wulff, M},
1124 Date-Added = {2012-12-17 16:52:34 +0000},
1125 Date-Modified = {2012-12-17 16:52:34 +0000},
1126 Doi = {DOI 10.1016/j.cplett.2004.11.072},
1127 Journal = cpl,
1128 Local-Url = {file://localhost/Users/charles/Documents/Papers/sdarticle3.pdf},
1129 Pages = {565-569},
1130 Title = {Thermal Dynamics in Laser Excited Metal Nanoparticles},
1131 Volume = {401},
1132 Year = {2005},
1133 Bdsk-Url-1 = {http://dx.doi.org/10.1016/j.cplett.2004.11.072}}
1134
1135 @article{Wilson:2002uq,
1136 Abstract = {We investigate suspensions of 3-10 nm diameter Au, Pt, and AuPd nanoparticles as probes of thermal transport in fluids and determine approximate values for the thermal conductance G of the particle/fluid interfaces. Subpicosecond lambda=770 nm optical pulses from a Ti:sapphire mode-locked laser are used to heat the particles and interrogate the decay of their temperature through time-resolved changes in optical absorption. The thermal decay of alkanethiol-terminated Au nanoparticles in toluene is partially obscured by other effects; we set a lower limit G>20 MW m(-2)K(-1). The thermal decay of citrate-stabilized Pt nanoparticles in water gives Gapproximate to130 MW m(-2) K-1. AuPd alloy nanoparticles in toluene and stabilized by alkanethiol termination give Gapproximate to5 MW m(-2) K-1. The measured G are within a factor of 2 of theoretical estimates based on the diffuse-mismatch model.},
1137 Author = {Wilson, OM and Hu, XY and Cahill, DG and Braun, PV},
1138 Date-Added = {2012-12-17 16:52:22 +0000},
1139 Date-Modified = {2013-02-18 17:34:52 +0000},
1140 Doi = {ARTN 224301},
1141 Journal = {Phys. Rev. B},
1142 Local-Url = {file://localhost/Users/charles/Documents/Papers/e2243010.pdf},
1143 Pages = {224301},
1144 Title = {Colloidal Metal Particles as Probes of Nanoscale Thermal Transport in Fluids},
1145 Volume = {66},
1146 Year = {2002},
1147 Bdsk-Url-1 = {http://dx.doi.org/224301}}
1148
1149 @article{Mazzaglia:2008to,
1150 Abstract = {Amphiphilic cyclodextrins (CDs) modified in the upper rim with thiohexyl groups and in the lower rim with oligoethylene amino (SC6NH2) or oligoethylene hydroxyl groups (SC6OH) can bind gold colloids, yielding Au/CD particles with an average hydrodynamic radius (RH) of 2 and 25 rim in water solution. The systems were investigated by UV-vis, quasi-elastic light scattering, and FTIR-ATR techniques. The concentration of amphiphiles was kept above the concentration of gold colloids to afford complete covering. In the case of SC6NH2, basic conditions (Et3N, pH 11) yield promptly the decoration of Au, which can be stabilized by linkage of CD amino and/or thioether groups. The critical aggregation concentration of SC6NH2 was measured (similar to 4 mu M) by surface tension measurements, pointing out that about 50\% of CDs are present in nonaggregated form. Whereas Au/SC6NH2 colloids were stable in size and morphology for at least one month, the size of the Au/SC6OH system increases remarkably, forming nanoaggregates of 20 and 80 rim in two hours. Under physiological conditions, the gold/amino amphiphiles system can internalize in HeLa cells, as shown by extinction spectra registered on the immobilized cells. The gold delivered by cyclodextrins can induce photothermal damage upon irradiation, doubling the cell mortality with respect to uncovered gold colloids. These findings can open useful perspectives to the application of these self-assembled systems in cancer photothermal therapy.},
1151 Address = {1155 16TH ST, NW, WASHINGTON, DC 20036 USA},
1152 Author = {Mazzaglia, Antonino and Trapani, Mariachiara and Villari, Valentina and Micali, Norberto and Merlo, Francesca Marino and Zaccaria, Daniela and Sciortino, Maria Teresa and Previti, Francesco and Patane, Salvatore and Scolaro, Luigi Monsu},
1153 Date = {MAY 1 2008},
1154 Date-Added = {2012-12-17 16:52:15 +0000},
1155 Date-Modified = {2012-12-17 16:52:15 +0000},
1156 Doi = {DOI 10.1021/jp7120033},
1157 Journal = jpcc,
1158 Pages = {6764-6769},
1159 Publisher = {AMER CHEMICAL SOC},
1160 Timescited = {0},
1161 Title = {Amphiphilic Cyclodextrins as Capping Agents for Gold Colloids: A Spectroscopic Investigation with Perspectives in Photothermal Therapy},
1162 Volume = {112},
1163 Year = {2008},
1164 Bdsk-Url-1 = {http://dx.doi.org/10.1021/jp7120033}}
1165
1166 @article{Gnyawali:2008lp,
1167 Abstract = {Tissue surface temperature distribution on the treatment site can serve as an indicator for the effectiveness of a photothermal therapy. In this study, both infrared thermography and theoretical simulation were used to determine the surface temperature distribution during laser irradiation of both gel phantom and animal tumors. Selective photothermal interaction was attempted by using intratumoral indocyanine green enhancement and irradiation via a near-infrared laser. An immunoadjuvant was also used to enhance immunological responses during tumor treatment. Monte Carlo method for tissue absorption of light and finite difference method for heat diffusion in tissue were used to simulate the temperature distribution during the selective laser photothermal interaction. An infrared camera was used to capture the thermal images during the laser treatment and the surface temperature was determined. Our findings show that the theoretical and experimental results are in good agreement and that the surface temperature of irradiated tissue can be controlled with appropriate dye and adjuvant enhancement. These results can be used to control the laser tumor treatment parameters and to optimize the treatment outcome. More importantly, when used with immunotherapy as a precursor of immunological responses, the selective photothermal treatment can be guided by the tissue temperature profiles both in the tumor and on the surface.},
1168 Address = {TIERGARTENSTRASSE 17, D-69121 HEIDELBERG, GERMANY},
1169 Author = {Gnyawali, Surya C. and Chen, Yicho and Wu, Feng and Bartels, Kenneth E. and Wicksted, James P. and Liu, Hong and Sen, Chandan K. and Chen, Wei R.},
1170 Date = {FEB 2008},
1171 Date-Added = {2012-12-17 16:52:08 +0000},
1172 Date-Modified = {2013-02-18 17:32:43 +0000},
1173 Doi = {DOI 10.1007/s11517-007-0251-5},
1174 Journal = {Med. Biol. Eng. Comput.},
1175 Keywords = {infrared thermography; indocyanine green; glycated chitosan; surface temperature; Monte Carlo simulation},
1176 Pages = {159-168},
1177 Publisher = {SPRINGER HEIDELBERG},
1178 Timescited = {0},
1179 Title = {Temperature Measurement on Tissue Surface During Laser Irradiation},
1180 Volume = {46},
1181 Year = {2008},
1182 Bdsk-Url-1 = {http://dx.doi.org/10.1007/s11517-007-0251-5}}
1183
1184 @article{Petrova:2007ad,
1185 Abstract = {This paper describes our recent time-resolved spectroscopy studies of the properties of gold particles at high laser excitation levels. In these experiments, an intense pump laser pulse rapidly heats the particle, creating very high lattice temperatures - up to the melting point of bulk gold. These high temperatures can have dramatic effects on the particle and the surroundings. The lattice temperature created is determined by observing the coherently excited the vibrational modes of the particles. The periods of these modes depend on temperature, thus, they act as an internal thermometer. We have used these experiments to provide values for the threshold temperatures for explosive boiling of the solvent surrounding the particles, and laser induced structural transformations in non-spherical particles. The results of these experiments are relevant to the use of metal nanoparticles in photothermal therapy, where laser induced heating is used to selectively kill cells.},
1186 Address = {LEKTORAT MINT, POSTFACH 80 13 60, D-81613 MUNICH, GERMANY},
1187 Author = {Petrova, Hristina and Hu, Min and Hartland, Gregory V.},
1188 Date = {2007},
1189 Date-Added = {2012-12-17 16:52:01 +0000},
1190 Date-Modified = {2013-02-18 17:32:23 +0000},
1191 Doi = {DOI 10.1524/zpch.2007.221.3.361},
1192 Journal = {Z Phys. Chem.},
1193 Keywords = {metal nanoparticles; phonon modes; photothermal properties; laser-induced heating},
1194 Pages = {361-376},
1195 Publisher = {OLDENBOURG VERLAG},
1196 Timescited = {2},
1197 Title = {Photothermal Properties of Gold Nanoparticles},
1198 Volume = {221},
1199 Year = {2007},
1200 Bdsk-Url-1 = {http://dx.doi.org/10.1524/zpch.2007.221.3.361}}
1201
1202 @article{Jain:2007ux,
1203 Abstract = {Noble metal, especially gold (Au) and silver (Ag) nanoparticles exhibit unique and tunable optical properties on account of their surface plasmon resonance (SPR). In this review, we discuss the SPR-enhanced optical properties of noble metal nanoparticles, with an emphasis on the recent advances in the utility of these plasmonic properties in molecular-specific imaging and sensing, photo-diagnostics, and selective photothermal therapy. The strongly enhanced SPR scattering from Au nanoparticles makes them useful as bright optical tags for molecular-specific biological imaging and detection using simple dark-field optical microscopy. On the other hand, the SPR absorption of the nanoparticles has allowed their use in the selective laser photothermal therapy of cancer. We also discuss the sensitivity of the nanoparticle SPR frequency to the local medium dielectric constant, which has been successfully exploited for the optical sensing of chemical and biological analytes. Plasmon coupling between metal nanoparticle pairs is also discussed, which forms the basis for nanoparticle assembly-based biodiagnostics and the plasmon ruler for dynamic measurement of nanoscale distances in biological systems.},
1204 Address = {233 SPRING STREET, NEW YORK, NY 10013 USA},
1205 Author = {Jain, Prashant K. and Huang, Xiaohua and El-Sayed, Ivan H. and El-Sayad, Mostafa A.},
1206 Date = {SEP 2007},
1207 Date-Added = {2012-12-17 16:51:52 +0000},
1208 Date-Modified = {2013-02-18 17:25:37 +0000},
1209 Doi = {DOI 10.1007/s11468-007-9031-1},
1210 Journal = {Plasmonics},
1211 Keywords = {surface plasmon resonance (SPR); SPR sensing; Mie scattering; metal nanocrystals for biodiagnostics; photothermal therapy; plasmon coupling},
1212 Number = {3},
1213 Pages = {107-118},
1214 Publisher = {SPRINGER},
1215 Timescited = {2},
1216 Title = {Review of Some Interesting Surface Plasmon Resonance-Enhanced Properties of Noble Metal Nanoparticles and Their Applications to Biosystems},
1217 Volume = {2},
1218 Year = {2007},
1219 Bdsk-Url-1 = {http://dx.doi.org/10.1007/s11468-007-9031-1}}
1220
1221 @techreport{Goddard1998,
1222 Author = {Kimura, Y. and Cagin, T. and Goddard III, W.A.},
1223 Date-Added = {2012-12-05 22:18:01 +0000},
1224 Date-Modified = {2012-12-05 22:18:01 +0000},
1225 Institution = {California Institute of Technology},
1226 Lastchecked = {January 19, 2011},
1227 Number = {003},
1228 Title = {The Quantum Sutton-Chen Many Body Potential for Properties of fcc Metals},
1229 Url = {http://csdrm.caltech.edu/publications/cit-asci-tr/cit-asci-tr003.pdf},
1230 Year = {1998},
1231 Bdsk-Url-1 = {http://csdrm.caltech.edu/publications/cit-asci-tr/cit-asci-tr003.pdf}}
1232
1233 @article{Kuang:2010if,
1234 Author = {Shenyu Kuang and J. Daniel Gezelter},
1235 Date-Added = {2012-12-05 22:18:01 +0000},
1236 Date-Modified = {2014-03-13 14:21:57 +0000},
1237 Journal = {J. Chem. Phys.},
1238 Keywords = {NIVS, RNEMD, NIVS-RNEMD},
1239 Month = {October},
1240 Pages = {164101-1 - 164101-9},
1241 Title = {A Gentler Approach to RNEMD: Nonisotropic Velocity Scaling for Computing Thermal Conductivity and Shear Viscosity},
1242 Volume = {133},
1243 Year = {2010}}
1244
1245 @article{Kuang:2012fe,
1246 Author = {Shenyu Kuang and J. Daniel Gezelter},
1247 Date-Added = {2012-12-05 22:18:01 +0000},
1248 Date-Modified = {2014-03-13 14:21:57 +0000},
1249 Journal = {Mol. Phys.},
1250 Keywords = {VSS, RNEMD, VSS-RNEMD},
1251 Month = {May},
1252 Number = {9-10},
1253 Pages = {691-701},
1254 Title = {Velocity Shearing and Scaling RNEMD: A Minimally Perturbing Method for Simulating Temperature and Momentum Gradients},
1255 Volume = {110},
1256 Year = {2012}}
1257
1258 @article{doi:10.1080/0026897031000068578,
1259 Abstract = { Using equilibrium and non-equilibrium molecular dynamics simulations, we determine the Kapitza resistance (or thermal contact resistance) at a model liquid-solid interface. The Kapitza resistance (or the associated Kapitza length) can reach appreciable values when the liquid does not wet the solid. The analogy with the hydrodynamic slip length is discussed. },
1260 Author = {Barrat, Jean-Louis and Chiaruttini, Fran{\c c}ois},
1261 Date-Added = {2011-12-13 17:17:05 -0500},
1262 Date-Modified = {2011-12-13 17:17:05 -0500},
1263 Doi = {10.1080/0026897031000068578},
1264 Eprint = {http://tandfprod.literatumonline.com/doi/pdf/10.1080/0026897031000068578},
1265 Journal = {Mol. Phys.},
1266 Number = {11},
1267 Pages = {1605-1610},
1268 Title = {Kapitza Resistance at the Liquid--Solid Interface},
1269 Url = {http://tandfprod.literatumonline.com/doi/abs/10.1080/0026897031000068578},
1270 Volume = {101},
1271 Year = {2003},
1272 Bdsk-Url-1 = {http://tandfprod.literatumonline.com/doi/abs/10.1080/0026897031000068578},
1273 Bdsk-Url-2 = {http://dx.doi.org/10.1080/0026897031000068578}}
1274
1275 @article{Medina2011,
1276 Abstract = {Molecular dynamics (MD) simulations are carried out on a system of rigid or flexible water molecules at a series of temperatures between 273 and 368&#xa0;K. Collective transport coefficients, such as shear and bulk viscosities are calculated, and their behavior is systematically investigated as a function of flexibility and temperature. It is found that by including the intramolecular terms in the potential the calculated viscosity values are in overall much better agreement, compared to earlier and recent available experimental data, than those obtained with the rigid SPC/E model. The effect of the intramolecular degrees of freedom on transport properties of liquid water is analyzed and the incorporation of polarizability is discussed for further improvements. To our knowledge the present study constitutes the first compendium of results on viscosities for pure liquid water, including flexible models, that has been assembled.},
1277 Author = {J.S. Medina and R. Prosmiti and P. Villarreal and G. Delgado-Barrio and G. Winter and B. Gonz{\'a}lez and J.V. Alem{\'a}n and C. Collado},
1278 Date-Added = {2011-12-13 17:08:34 -0500},
1279 Date-Modified = {2011-12-13 17:08:49 -0500},
1280 Doi = {10.1016/j.chemphys.2011.07.001},
1281 Issn = {0301-0104},
1282 Journal = {Chemical Physics},
1283 Keywords = {Viscosity calculations},
1284 Number = {1-3},
1285 Pages = {9 - 18},
1286 Title = {Molecular Dynamics Simulations of Rigid and Flexible Water Models: Temperature Dependence of Viscosity},
1287 Url = {http://www.sciencedirect.com/science/article/pii/S0301010411002813},
1288 Volume = {388},
1289 Year = {2011},
1290 Bdsk-Url-1 = {http://www.sciencedirect.com/science/article/pii/S0301010411002813},
1291 Bdsk-Url-2 = {http://dx.doi.org/10.1016/j.chemphys.2011.07.001}}
1292
1293 @book{WagnerKruse,
1294 Address = {Berlin},
1295 Author = {W. Wagner and A. Kruse},
1296 Date-Added = {2011-12-13 14:57:08 -0500},
1297 Date-Modified = {2011-12-13 14:57:08 -0500},
1298 Publisher = {Springer-Verlag},
1299 Title = {Properties of Water and Steam, the Industrial Standard IAPWS-IF97 for the Thermodynamic Properties and Supplementary Equations for Other Properties},
1300 Year = {1998}}
1301
1302 @article{Shenogina:2009ix,
1303 Author = {Shenogina, Natalia and Godawat, Rahul and Keblinski, Pawel and Garde, Shekhar},
1304 Date-Added = {2011-12-13 12:48:51 -0500},
1305 Date-Modified = {2014-03-13 14:21:57 +0000},
1306 Doi = {10.1103/PhysRevLett.102.156101},
1307 Journal = {Phys. Rev. Lett.},
1308 Month = {Apr},
1309 Number = {15},
1310 Numpages = {4},
1311 Pages = {156101},
1312 Publisher = {American Physical Society},
1313 Title = {How Wetting and Adhesion Affect Thermal Conductance of a Range of Hydrophobic to Hydrophilic Aqueous Interfaces},
1314 Volume = {102},
1315 Year = {2009},
1316 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRevLett.102.156101}}
1317
1318 @article{Patel:2005zm,
1319 Abstract = { Systems with nanoscopic features contain a high density of interfaces. Thermal transport in such systems can be governed by the resistance to heat transfer, the Kapitza resistance (RK), at the interface. Although soft interfaces, such as those between immiscible liquids or between a biomolecule and solvent, are ubiquitous, few studies of thermal transport at such interfaces have been reported. Here we characterize the interfacial conductance, 1/RK, of soft interfaces as a function of molecular architecture, chemistry, and the strength of cross-interfacial intermolecular interactions through detailed molecular dynamics simulations. The conductance of various interfaces studied here, for example, water−organic liquid, water−surfactant, surfactant−organic liquid, is relatively high (in the range of 65−370 MW/m2 K) compared to that for solid−liquid interfaces (∼10 MW/m2 K). Interestingly, the dependence of interfacial conductance on the chemistry and molecular architecture cannot be explained solely in terms of either bulk property mismatch or the strength of intermolecular attraction between the two phases. The observed trends can be attributed to a combination of strong cross-interface intermolecular interactions and good thermal coupling via soft vibration modes present at liquid−liquid interfaces. },
1320 Annote = {PMID: 16277458},
1321 Author = {Patel, Harshit A. and Garde, Shekhar and Keblinski, Pawel},
1322 Date-Added = {2011-12-13 12:48:51 -0500},
1323 Date-Modified = {2014-03-13 20:42:07 +0000},
1324 Doi = {10.1021/nl051526q},
1325 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/nl051526q},
1326 Journal = {Nano Lett.},
1327 Number = {11},
1328 Pages = {2225-2231},
1329 Title = {Thermal Resistance of Nanoscopic Liquid-Liquid Interfaces: Dependence on Chemistry and Molecular Architecture},
1330 Url = {http://pubs.acs.org/doi/abs/10.1021/nl051526q},
1331 Volume = {5},
1332 Year = {2005},
1333 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/nl051526q},
1334 Bdsk-Url-2 = {http://dx.doi.org/10.1021/nl051526q}}
1335
1336 @article{melchionna93,
1337 Author = {S. Melchionna and G. Ciccotti and B.~L. Holian},
1338 Date-Added = {2011-12-12 17:52:15 -0500},
1339 Date-Modified = {2011-12-12 17:52:15 -0500},
1340 Journal = {Mol. Phys.},
1341 Pages = {533-544},
1342 Title = {Hoover {\sc NPT} Dynamics for Systems Varying in Shape and Size},
1343 Volume = 78,
1344 Year = 1993}
1345
1346 @article{TraPPE-UA.thiols,
1347 Author = {Lubna, Nusrat and Kamath, Ganesh and Potoff, Jeffrey J. and Rai, Neeraj and Siepmann, J. Ilja},
1348 Date-Added = {2011-12-07 15:06:12 -0500},
1349 Date-Modified = {2011-12-07 15:06:12 -0500},
1350 Doi = {10.1021/jp0549125},
1351 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/jp0549125},
1352 Journal = {J. Phys. Chem. B},
1353 Number = {50},
1354 Pages = {24100-24107},
1355 Title = {Transferable Potentials for Phase Equilibria. 8. United-Atom Description for Thiols, Sulfides, Disulfides, and Thiophene},
1356 Url = {http://pubs.acs.org/doi/abs/10.1021/jp0549125},
1357 Volume = {109},
1358 Year = {2005},
1359 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/jp0549125},
1360 Bdsk-Url-2 = {http://dx.doi.org/10.1021/jp0549125}}
1361
1362 @article{TraPPE-UA.alkylbenzenes,
1363 Author = {Wick, Collin D. and Martin, Marcus G. and Siepmann, J. Ilja},
1364 Date-Added = {2011-12-07 15:06:12 -0500},
1365 Date-Modified = {2011-12-07 15:06:12 -0500},
1366 Doi = {10.1021/jp001044x},
1367 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/jp001044x},
1368 Journal = {J. Phys. Chem. B},
1369 Number = {33},
1370 Pages = {8008-8016},
1371 Title = {Transferable Potentials for Phase Equilibria. 4. United-Atom Description of Linear and Branched Alkenes and Alkylbenzenes},
1372 Url = {http://pubs.acs.org/doi/abs/10.1021/jp001044x},
1373 Volume = {104},
1374 Year = {2000},
1375 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/jp001044x},
1376 Bdsk-Url-2 = {http://dx.doi.org/10.1021/jp001044x}}
1377
1378 @article{TraPPE-UA.alkanes,
1379 Author = {Martin, Marcus G. and Siepmann, J. Ilja},
1380 Date-Added = {2011-12-07 15:06:12 -0500},
1381 Date-Modified = {2011-12-07 15:06:12 -0500},
1382 Doi = {10.1021/jp972543+},
1383 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/jp972543%2B},
1384 Journal = {J. Phys. Chem. B},
1385 Number = {14},
1386 Pages = {2569-2577},
1387 Title = {Transferable Potentials for Phase Equilibria. 1. United-Atom Description of n-Alkanes},
1388 Url = {http://pubs.acs.org/doi/abs/10.1021/jp972543%2B},
1389 Volume = {102},
1390 Year = {1998},
1391 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/jp972543+},
1392 Bdsk-Url-2 = {http://dx.doi.org/10.1021/jp972543+},
1393 Bdsk-Url-3 = {http://pubs.acs.org/doi/abs/10.1021/jp972543%2B}}
1394
1395 @article{ISI:000167766600035,
1396 Abstract = {Molecular dynamics simulations are used to
1397 investigate the separation of water films adjacent
1398 to a hot metal surface. The simulations clearly show
1399 that the water layers nearest the surface overheat
1400 and undergo explosive boiling. For thick films, the
1401 expansion of the vaporized molecules near the
1402 surface forces the outer water layers to move away
1403 from the surface. These results are of interest for
1404 mass spectrometry of biological molecules, steam
1405 cleaning of surfaces, and medical procedures.},
1406 Address = {1155 16TH ST, NW, WASHINGTON, DC 20036 USA},
1407 Affiliation = {Garrison, BJ (Reprint Author), Penn State Univ, Dept Chem, University Pk, PA 16802 USA. Penn State Univ, Dept Chem, University Pk, PA 16802 USA. Penn State Univ, Inst Mat Res, University Pk, PA 16802 USA. Univ Virginia, Dept Mat Sci \& Engn, Charlottesville, VA 22903 USA.},
1408 Author = {Dou, YS and Zhigilei, LV and Winograd, N and Garrison, BJ},
1409 Date-Added = {2011-12-07 15:02:32 -0500},
1410 Date-Modified = {2011-12-07 15:02:32 -0500},
1411 Doc-Delivery-Number = {416ED},
1412 Issn = {1089-5639},
1413 Journal = {J. Phys. Chem. A},
1414 Journal-Iso = {J. Phys. Chem. A},
1415 Keywords-Plus = {MOLECULAR-DYNAMICS SIMULATIONS; ASSISTED LASER-DESORPTION; FROZEN AQUEOUS-SOLUTIONS; COMPUTER-SIMULATION; ORGANIC-SOLIDS; VELOCITY DISTRIBUTIONS; PARTICLE BOMBARDMENT; MASS-SPECTROMETRY; PHASE EXPLOSION; LIQUID WATER},
1416 Language = {English},
1417 Month = {MAR 29},
1418 Number = {12},
1419 Number-Of-Cited-References = {65},
1420 Pages = {2748-2755},
1421 Publisher = {AMER CHEMICAL SOC},
1422 Subject-Category = {Chemistry, Physical; Physics, Atomic, Molecular \& Chemical},
1423 Times-Cited = {66},
1424 Title = {Explosive Boiling of Water Films Adjacent to Heated Surfaces: A Microscopic Description},
1425 Type = {Article},
1426 Unique-Id = {ISI:000167766600035},
1427 Volume = {105},
1428 Year = {2001}}
1429
1430 @article{Chen90,
1431 Author = {A.~P. Sutton and J. Chen},
1432 Date-Added = {2011-12-07 15:01:59 -0500},
1433 Date-Modified = {2013-02-18 18:01:16 +0000},
1434 Journal = {Phil. Mag. Lett.},
1435 Pages = {139-146},
1436 Title = {Long-Range Finnis Sinclair Potentials},
1437 Volume = 61,
1438 Year = {1990}}
1439
1440 @article{PhysRevB.59.3527,
1441 Author = {Qi, Yue and \c{C}a\v{g}in, Tahir and Kimura, Yoshitaka and {Goddard III}, William A.},
1442 Date-Added = {2011-12-07 15:01:36 -0500},
1443 Date-Modified = {2013-02-18 18:00:57 +0000},
1444 Doi = {10.1103/PhysRevB.59.3527},
1445 Journal = {Phys. Rev. B},
1446 Local-Url = {file://localhost/Users/charles/Documents/Papers/Qi/1999.pdf},
1447 Month = {Feb},
1448 Number = {5},
1449 Numpages = {6},
1450 Pages = {3527-3533},
1451 Publisher = {American Physical Society},
1452 Title = {Molecular-Dynamics Simulations of Glass Formation and Crystallization in Binary Liquid Metals: {C}u-{A}g and {C}u-{N}i},
1453 Volume = {59},
1454 Year = {1999},
1455 Bdsk-Url-1 = {http://dx.doi.org/10.1103/PhysRevB.59.3527}}
1456
1457 @article{Bedrov:2000,
1458 Abstract = {We have applied a new nonequilibrium molecular
1459 dynamics (NEMD) method {[}F. Muller-Plathe,
1460 J. Chem. Phys. 106, 6082 (1997)] previously applied
1461 to monatomic Lennard-Jones fluids in the
1462 determination of the thermal conductivity of
1463 molecular fluids. The method was modified in order
1464 to be applicable to systems with holonomic
1465 constraints. Because the method involves imposing a
1466 known heat flux it is particularly attractive for
1467 systems involving long-range and many-body
1468 interactions where calculation of the microscopic
1469 heat flux is difficult. The predicted thermal
1470 conductivities of liquid n-butane and water using
1471 the imposed-flux NEMD method were found to be in a
1472 good agreement with previous simulations and
1473 experiment. (C) 2000 American Institute of
1474 Physics. {[}S0021-9606(00)50841-1].},
1475 Address = {2 HUNTINGTON QUADRANGLE, STE 1NO1, MELVILLE, NY 11747-4501 USA},
1476 Affiliation = {Bedrov, D (Reprint Author), Univ Utah, Dept Chem \& Fuels Engn, 122 S Cent Campus Dr,Rm 304, Salt Lake City, UT 84112 USA. Univ Utah, Dept Chem \& Fuels Engn, Salt Lake City, UT 84112 USA. Univ Utah, Dept Mat Sci \& Engn, Salt Lake City, UT 84112 USA.},
1477 Author = {Bedrov, D and Smith, GD},
1478 Date-Added = {2011-12-07 15:00:27 -0500},
1479 Date-Modified = {2011-12-07 15:00:27 -0500},
1480 Doc-Delivery-Number = {369BF},
1481 Issn = {0021-9606},
1482 Journal = {J. Chem. Phys.},
1483 Journal-Iso = {J. Chem. Phys.},
1484 Keywords-Plus = {EFFECTIVE PAIR POTENTIALS; TRANSPORT-PROPERTIES; CANONICAL ENSEMBLE; NORMAL-BUTANE; ALGORITHMS; SHAKE; WATER},
1485 Language = {English},
1486 Month = {NOV 8},
1487 Number = {18},
1488 Number-Of-Cited-References = {26},
1489 Pages = {8080-8084},
1490 Publisher = {AMER INST PHYSICS},
1491 Read = {1},
1492 Subject-Category = {Physics, Atomic, Molecular \& Chemical},
1493 Times-Cited = {23},
1494 Title = {Thermal Conductivity of Molecular Fluids from Molecular Dynamics Simulations: Application of a New Imposed-Flux Method},
1495 Type = {Article},
1496 Unique-Id = {ISI:000090151400044},
1497 Volume = {113},
1498 Year = {2000}}
1499
1500 @article{10.1063/1.3330544,
1501 Author = {Miguel Angel Gonz{\'a}lez and Jos{\'e} L. F. Abascal},
1502 Coden = {JCPSA6},
1503 Date-Added = {2011-12-07 14:59:20 -0500},
1504 Date-Modified = {2011-12-15 13:10:11 -0500},
1505 Doi = {DOI:10.1063/1.3330544},
1506 Eissn = {10897690},
1507 Issn = {00219606},
1508 Journal = {J. Chem. Phys.},
1509 Keywords = {shear strength; viscosity;},
1510 Number = {9},
1511 Pages = {096101},
1512 Publisher = {AIP},
1513 Title = {The Shear Viscosity of Rigid Water Models},
1514 Url = {http://dx.doi.org/doi/10.1063/1.3330544},
1515 Volume = {132},
1516 Year = {2010},
1517 Bdsk-Url-1 = {http://dx.doi.org/doi/10.1063/1.3330544},
1518 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.3330544}}
1519
1520 @article{doi:10.1021/jp048434u,
1521 Abstract = { The different possible proton-ordered structures of ice Ih for an orthorombic unit cell with 8 water molecules were derived. The number of unique structures was found to be 16. The crystallographic coordinates of these are reported. The energetics of the different polymorphs were investigated by quantum-mechanical density-functional theory calculations and for comparison by molecular-mechanics analytical potential models. The polymorphs were found to be close in energy, i.e., within approximately 0.25 kcal/mol H2O, on the basis of the quantum-chemical DFT methods. At 277 K, the different energy levels are about evenly populated, but at a lower temperature, a transition to an ordered form is expected. This form was found to agree with the ice phase XI. The difference in lattice energies among the polymorphs was rationalized in terms of structural characteristics. The most important parameters to determine the lattice energies were found to be the distributions of water dimer H-bonded pair conformations, in an intricate manner. },
1522 Author = {Hirsch, Tomas K. and Ojam{\"a}e, Lars},
1523 Date-Added = {2011-12-07 14:38:30 -0500},
1524 Date-Modified = {2011-12-07 14:38:30 -0500},
1525 Doi = {10.1021/jp048434u},
1526 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/jp048434u},
1527 Journal = {J. Phys. Chem. B},
1528 Number = {40},
1529 Pages = {15856-15864},
1530 Title = {Quantum-Chemical and Force-Field Investigations of Ice Ih:  Computation of Proton-Ordered Structures and Prediction of Their Lattice Energies},
1531 Url = {http://pubs.acs.org/doi/abs/10.1021/jp048434u},
1532 Volume = {108},
1533 Year = {2004},
1534 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/jp048434u},
1535 Bdsk-Url-2 = {http://dx.doi.org/10.1021/jp048434u}}
1536
1537 @article{Meineke:2005gd,
1538 Abstract = {OOPSE is a new molecular dynamics simulation program
1539 that is capable of efficiently integrating equations
1540 of motion for atom types with orientational degrees
1541 of freedom (e.g. #sticky# atoms and point
1542 dipoles). Transition metals can also be simulated
1543 using the embedded atom method (EAM) potential
1544 included in the code. Parallel simulations are
1545 carried out using the force-based decomposition
1546 method. Simulations are specified using a very
1547 simple C-based meta-data language. A number of
1548 advanced integrators are included, and the basic
1549 integrator for orientational dynamics provides
1550 substantial improvements over older quaternion-based
1551 schemes.},
1552 Address = {111 RIVER ST, HOBOKEN, NJ 07030 USA},
1553 Author = {Meineke, M. A. and Vardeman, C. F. and Lin, T and Fennell, CJ and Gezelter, J. D.},
1554 Date-Added = {2011-12-07 13:33:04 -0500},
1555 Date-Modified = {2011-12-07 13:33:04 -0500},
1556 Doi = {DOI 10.1002/jcc.20161},
1557 Isi = {000226558200006},
1558 Isi-Recid = {142688207},
1559 Isi-Ref-Recids = {67885400 50663994 64190493 93668415 46699855 89992422 57614458 49016001 61447131 111114169 68770425 52728075 102422498 66381878 32391149 134477335 53221357 9929643 59492217 69681001 99223832 142688208 94600872 91658572 54857943 117365867 69323123 49588888 109970172 101670714 142688209 121603296 94652379 96449138 99938010 112825758 114905670 86802042 121339042 104794914 82674909 72096791 93668384 90513335 142688210 23060767 63731466 109033408 76303716 31384453 97861662 71842426 130707771 125809946 66381889 99676497},
1560 Journal = {J. Comput. Chem.},
1561 Keywords = {OOPSE; molecular dynamics},
1562 Month = feb,
1563 Number = {3},
1564 Pages = {252-271},
1565 Publisher = {JOHN WILEY \& SONS INC},
1566 Times-Cited = {9},
1567 Title = {OOPSE: An Object-Oriented Parallel Simulation Engine for Molecular Dynamics},
1568 Volume = {26},
1569 Year = {2005},
1570 Bdsk-Url-1 = {http://gateway.isiknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=Alerting&SrcApp=Alerting&DestApp=WOS&DestLinkType=FullRecord;KeyUT=000226558200006},
1571 Bdsk-Url-2 = {http://dx.doi.org/10.1002/jcc.20161}}
1572
1573 @article{hoover85,
1574 Author = {W.~G. Hoover},
1575 Date-Added = {2011-12-06 14:23:41 -0500},
1576 Date-Modified = {2011-12-06 14:23:41 -0500},
1577 Journal = {Phys. Rev. A},
1578 Pages = 1695,
1579 Title = {Canonical Dynamics: Equilibrium Phase-Space Distributions},
1580 Volume = 31,
1581 Year = 1985}
1582
1583 @article{Tenney:2010rp,
1584 Abstract = {The reverse nonequilibrium molecular dynamics
1585 (RNEMD) method calculates the shear viscosity of a
1586 fluid by imposing a nonphysical exchange of momentum
1587 and measuring the resulting shear velocity
1588 gradient. In this study we investigate the range of
1589 momentum flux values over which RNEMD yields usable
1590 (linear) velocity gradients. We find that nonlinear
1591 velocity profiles result primarily from gradients in
1592 fluid temperature and density. The temperature
1593 gradient results from conversion of heat into bulk
1594 kinetic energy, which is transformed back into heat
1595 elsewhere via viscous heating. An expression is
1596 derived to predict the temperature profile resulting
1597 from a specified momentum flux for a given fluid and
1598 simulation cell. Although primarily bounded above,
1599 we also describe milder low-flux limitations. RNEMD
1600 results for a Lennard-Jones fluid agree with
1601 equilibrium molecular dynamics and conventional
1602 nonequilibrium molecular dynamics calculations at
1603 low shear, but RNEMD underpredicts viscosity
1604 relative to conventional NEMD at high shear.},
1605 Address = {CIRCULATION \& FULFILLMENT DIV, 2 HUNTINGTON QUADRANGLE, STE 1 N O 1, MELVILLE, NY 11747-4501 USA},
1606 Affiliation = {Tenney, CM (Reprint Author), Univ Notre Dame, Dept Chem \& Biomol Engn, 182 Fitzpatrick Hall, Notre Dame, IN 46556 USA. {[}Tenney, Craig M.; Maginn, Edward J.] Univ Notre Dame, Dept Chem \& Biomol Engn, Notre Dame, IN 46556 USA.},
1607 Article-Number = {014103},
1608 Author = {Tenney, Craig M. and Maginn, Edward J.},
1609 Author-Email = {ed@nd.edu},
1610 Date-Added = {2011-12-05 18:29:08 -0500},
1611 Date-Modified = {2014-03-13 14:21:57 +0000},
1612 Doc-Delivery-Number = {542DQ},
1613 Doi = {10.1063/1.3276454},
1614 Funding-Acknowledgement = {U.S. Department of Energy {[}DE-FG36-08G088020]},
1615 Funding-Text = {Support for this work was provided by the U.S. Department of Energy (Grant No. DE-FG36-08G088020)},
1616 Issn = {0021-9606},
1617 Journal = {J. Chem. Phys.},
1618 Journal-Iso = {J. Chem. Phys.},
1619 Keywords = {Lennard-Jones potential; molecular dynamics method; Navier-Stokes equations; viscosity},
1620 Keywords-Plus = {CURRENT AUTOCORRELATION-FUNCTION; IONIC LIQUID; SIMULATIONS; TEMPERATURE},
1621 Language = {English},
1622 Month = {JAN 7},
1623 Number = {1},
1624 Number-Of-Cited-References = {20},
1625 Pages = {014103},
1626 Publisher = {AMER INST PHYSICS},
1627 Subject-Category = {Physics, Atomic, Molecular \& Chemical},
1628 Times-Cited = {0},
1629 Title = {Limitations and Recommendations for the Calculation of Shear Viscosity using Reverse Nonequilibrium Molecular Dynamics},
1630 Type = {Article},
1631 Unique-Id = {ISI:000273472300004},
1632 Volume = {132},
1633 Year = {2010},
1634 Bdsk-Url-1 = {http://dx.doi.org/10.1063/1.3276454}}
1635
1636 @article{Muller-Plathe:1999ao,
1637 Abstract = {A nonequilibrium method for calculating the shear
1638 viscosity is presented. It reverses the
1639 cause-and-effect picture customarily used in
1640 nonequilibrium molecular dynamics: the effect, the
1641 momentum flux or stress, is imposed, whereas the
1642 cause, the velocity gradient or shear rate, is
1643 obtained from the simulation. It differs from other
1644 Norton-ensemble methods by the way in which the
1645 steady-state momentum flux is maintained. This
1646 method involves a simple exchange of particle
1647 momenta, which is easy to implement. Moreover, it
1648 can be made to conserve the total energy as well as
1649 the total linear momentum, so no coupling to an
1650 external temperature bath is needed. The resulting
1651 raw data, the velocity profile, is a robust and
1652 rapidly converging property. The method is tested on
1653 the Lennard-Jones fluid near its triple point. It
1654 yields a viscosity of 3.2-3.3, in Lennard-Jones
1655 reduced units, in agreement with literature
1656 results. {[}S1063-651X(99)03105-0].},
1657 Address = {ONE PHYSICS ELLIPSE, COLLEGE PK, MD 20740-3844 USA},
1658 Affiliation = {Muller-Plathe, F (Reprint Author), Max Planck Inst Polymerforsch, Ackermannweg 10, D-55128 Mainz, Germany. Max Planck Inst Polymerforsch, D-55128 Mainz, Germany.},
1659 Author = {M\"{u}ller-Plathe, F},
1660 Date-Added = {2011-12-05 18:18:37 -0500},
1661 Date-Modified = {2014-03-13 14:21:57 +0000},
1662 Doc-Delivery-Number = {197TX},
1663 Issn = {1063-651X},
1664 Journal = {Phys. Rev. E},
1665 Journal-Iso = {Phys. Rev. E},
1666 Language = {English},
1667 Month = {MAY},
1668 Number = {5, Part A},
1669 Number-Of-Cited-References = {17},
1670 Pages = {4894-4898},
1671 Publisher = {AMERICAN PHYSICAL SOC},
1672 Subject-Category = {Physics, Fluids \& Plasmas; Physics, Mathematical},
1673 Times-Cited = {57},
1674 Title = {Reversing the Perturbation in Nonequilibrium Molecular Dynamics: An Easy Way to Calculate the Shear Viscosity of Fluids},
1675 Type = {Article},
1676 Unique-Id = {ISI:000080382700030},
1677 Volume = {59},
1678 Year = {1999}}
1679
1680 @article{Muller-Plathe:1997wq,
1681 Abstract = {A nonequilibrium molecular dynamics method for
1682 calculating the thermal conductivity is
1683 presented. It reverses the usual cause and effect
1684 picture. The ''effect,'' the heat flux, is imposed
1685 on the system and the ''cause,'' the temperature
1686 gradient is obtained from the simulation. Besides
1687 being very simple to implement, the scheme offers
1688 several advantages such as compatibility with
1689 periodic boundary conditions, conservation of total
1690 energy and total linear momentum, and the sampling
1691 of a rapidly converging quantity (temperature
1692 gradient) rather than a slowly converging one (heat
1693 flux). The scheme is tested on the Lennard-Jones
1694 fluid. (C) 1997 American Institute of Physics.},
1695 Address = {WOODBURY},
1696 Author = {M\"{u}ller-Plathe, F.},
1697 Cited-Reference-Count = {13},
1698 Date = {APR 8},
1699 Date-Added = {2011-12-05 18:18:37 -0500},
1700 Date-Modified = {2014-03-13 14:21:57 +0000},
1701 Document-Type = {Article},
1702 Isi = {ISI:A1997WR62000032},
1703 Isi-Document-Delivery-Number = {WR620},
1704 Iso-Source-Abbreviation = {J. Chem. Phys.},
1705 Issn = {0021-9606},
1706 Journal = {J. Chem. Phys.},
1707 Language = {English},
1708 Month = {Apr},
1709 Number = {14},
1710 Page-Count = {4},
1711 Pages = {6082--6085},
1712 Publication-Type = {J},
1713 Publisher = {AMER INST PHYSICS},
1714 Publisher-Address = {CIRCULATION FULFILLMENT DIV, 500 SUNNYSIDE BLVD, WOODBURY, NY 11797-2999},
1715 Reprint-Address = {MullerPlathe, F, MAX PLANCK INST POLYMER RES, D-55128 MAINZ, GERMANY.},
1716 Source = {J CHEM PHYS},
1717 Subject-Category = {Physics, Atomic, Molecular & Chemical},
1718 Times-Cited = {106},
1719 Title = {A Simple Nonequilibrium Molecular Dynamics Method for Calculating the Thermal Conductivity},
1720 Volume = {106},
1721 Year = {1997}}
1722
1723 @article{priezjev:204704,
1724 Author = {Nikolai V. Priezjev},
1725 Date-Added = {2011-11-28 14:39:18 -0500},
1726 Date-Modified = {2011-11-28 14:39:18 -0500},
1727 Doi = {10.1063/1.3663384},
1728 Eid = {204704},
1729 Journal = {J. Chem. Phys.},
1730 Keywords = {channel flow; diffusion; flow simulation; hydrodynamics; molecular dynamics method; pattern formation; random processes; shear flow; slip flow; wetting},
1731 Number = {20},
1732 Numpages = {9},
1733 Pages = {204704},
1734 Publisher = {AIP},
1735 Title = {Molecular Diffusion and Slip Boundary Conditions at Smooth Surfaces with Periodic and Random Nanoscale Textures},
1736 Url = {http://link.aip.org/link/?JCP/135/204704/1},
1737 Volume = {135},
1738 Year = {2011},
1739 Bdsk-Url-1 = {http://link.aip.org/link/?JCP/135/204704/1},
1740 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.3663384}}
1741
1742 @article{bryk:10258,
1743 Author = {Taras Bryk and A. D. J. Haymet},
1744 Date-Added = {2011-11-22 17:06:35 -0500},
1745 Date-Modified = {2011-11-22 17:06:35 -0500},
1746 Doi = {10.1063/1.1519538},
1747 Journal = {J. Chem. Phys.},
1748 Keywords = {liquid structure; molecular dynamics method; water; ice; interface structure},
1749 Number = {22},
1750 Pages = {10258-10268},
1751 Publisher = {AIP},
1752 Title = {Ice 1h/Water Interface of the SPC/E Model: Molecular Dynamics Simulations of the Equilibrium Basal and Prism Interfaces},
1753 Url = {http://link.aip.org/link/?JCP/117/10258/1},
1754 Volume = {117},
1755 Year = {2002},
1756 Bdsk-Url-1 = {http://link.aip.org/link/?JCP/117/10258/1},
1757 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.1519538}}
1758
1759 @book{openmd,
1760 Author = {J. Daniel Gezelter and Shenyu Kuang and James Marr and Kelsey Stocker and Chunlei Li and Charles F. Vardeman and Teng Lin and Christopher J. Fennell and Xiuquan Sun and Kyle Daily and Yang Zheng and Matthew A. Meineke},
1761 Date-Added = {2011-11-18 15:32:23 -0500},
1762 Date-Modified = {2014-04-10 21:12:31 +0000},
1763 Publisher = {An open source molecular dynamics engine},
1764 Title = {OpenMD},
1765 Url = {http://openmd.org (accessed 11/13/2013)},
1766 Year = {version 2.1, {\tt http://openmd.org} (accessed 11/13/2013)}}
1767
1768 @article{Kuang:2011ef,
1769 Author = {Kuang, Shenyu and Gezelter, J. Daniel},
1770 Date-Added = {2011-11-18 13:03:06 -0500},
1771 Date-Modified = {2014-03-13 14:21:57 +0000},
1772 Doi = {10.1021/jp2073478},
1773 Eprint = {http://pubs.acs.org/doi/pdf/10.1021/jp2073478},
1774 Journal = {J. Phys. Chem. C},
1775 Number = {45},
1776 Pages = {22475-22483},
1777 Title = {Simulating Interfacial Thermal Conductance at Metal-Solvent Interfaces: The Role of Chemical Capping Agents},
1778 Url = {http://pubs.acs.org/doi/abs/10.1021/jp2073478},
1779 Volume = {115},
1780 Year = {2011},
1781 Bdsk-Url-1 = {http://pubs.acs.org/doi/abs/10.1021/jp2073478},
1782 Bdsk-Url-2 = {http://dx.doi.org/10.1021/jp2073478}}
1783
1784 @article{10.1063/1.2772547,
1785 Author = {Hideo Kaburaki and Ju Li and Sidney Yip and Hajime Kimizuka},
1786 Coden = {JAPIAU},
1787 Date-Added = {2011-11-01 16:46:32 -0400},
1788 Date-Modified = {2011-11-01 16:46:32 -0400},
1789 Doi = {DOI:10.1063/1.2772547},
1790 Eissn = {10897550},
1791 Issn = {00218979},
1792 Keywords = {argon; Lennard-Jones potential; phonons; thermal conductivity;},
1793 Number = {4},
1794 Pages = {043514},
1795 Publisher = {AIP},
1796 Title = {Dynamical Thermal Conductivity of Argon Crystal},
1797 Url = {http://dx.doi.org/10.1063/1.2772547},
1798 Volume = {102},
1799 Year = {2007},
1800 Bdsk-Url-1 = {http://dx.doi.org/10.1063/1.2772547}}
1801
1802 @article{PhysRevLett.82.4671,
1803 Author = {Barrat, Jean-Louis and Bocquet, Lyd\'eric},
1804 Date-Added = {2011-11-01 16:44:29 -0400},
1805 Date-Modified = {2011-11-01 16:44:29 -0400},
1806 Doi = {10.1103/PhysRevLett.82.4671},
1807 Issue = {23},
1808 Journal = {Phys. Rev. Lett.},
1809 Month = {Jun},
1810 Pages = {4671--4674},
1811 Publisher = {American Physical Society},
1812 Title = {Large Slip Effect at a Nonwetting Fluid-Solid Interface},
1813 Url = {http://link.aps.org/doi/10.1103/PhysRevLett.82.4671},
1814 Volume = {82},
1815 Year = {1999},
1816 Bdsk-Url-1 = {http://link.aps.org/doi/10.1103/PhysRevLett.82.4671},
1817 Bdsk-Url-2 = {http://dx.doi.org/10.1103/PhysRevLett.82.4671}}
1818
1819 @article{10.1063/1.1610442,
1820 Author = {J. R. Schmidt and J. L. Skinner},
1821 Coden = {JCPSA6},
1822 Date-Added = {2011-10-13 16:28:43 -0400},
1823 Date-Modified = {2011-12-15 13:11:53 -0500},
1824 Doi = {DOI:10.1063/1.1610442},
1825 Eissn = {10897690},
1826 Issn = {00219606},
1827 Journal = {J. Chem. Phys.},
1828 Keywords = {hydrodynamics; Brownian motion; molecular dynamics method; diffusion;},
1829 Number = {15},
1830 Pages = {8062-8068},
1831 Publisher = {AIP},
1832 Title = {Hydrodynamic Boundary Conditions, the Stokes?Einstein Law, and Long-Time Tails in the Brownian Limit},
1833 Url = {http://dx.doi.org/10.1063/1.1610442},
1834 Volume = {119},
1835 Year = {2003},
1836 Bdsk-Url-1 = {http://dx.doi.org/10.1063/1.1610442}}
1837
1838 @article{10.1063/1.3274802,
1839 Author = {Ting Chen and Berend Smit and Alexis T. Bell},
1840 Coden = {JCPSA6},
1841 Doi = {DOI:10.1063/1.3274802},
1842 Eissn = {10897690},
1843 Issn = {00219606},
1844 Keywords = {fluctuations; molecular dynamics method; viscosity;},
1845 Number = {24},
1846 Pages = {246101},
1847 Publisher = {AIP},
1848 Title = {Are Pressure Fluctuation-Based Equilibrium Methods Really Worse than Nonequilibrium Methods for Calculating Viscosities?},
1849 Url = {http://dx.doi.org/doi/10.1063/1.3274802},
1850 Volume = {131},
1851 Year = {2009},
1852 Bdsk-Url-1 = {http://dx.doi.org/doi/10.1063/1.3274802},
1853 Bdsk-Url-2 = {http://dx.doi.org/10.1063/1.3274802}}
1854
1855 @comment{BibDesk Static Groups{
1856 <?xml version="1.0" encoding="UTF-8"?>
1857 <!DOCTYPE plist PUBLIC "-//Apple//DTD PLIST 1.0//EN" "http://www.apple.com/DTDs/PropertyList-1.0.dtd">
1858 <plist version="1.0">
1859 <array>
1860 <dict>
1861 <key>group name</key>
1862 <string>NEMD</string>
1863 <key>keys</key>
1864 <string>Ashurst:1975eu,Hess:2002nr,Evans:2002tg,Picalek:2009rz,Backer:2005sf,Erpenbeck:1984qe,Schelling:2002dp,Maginn:1993kl,Berthier:2002ai,Evans:1986nx,Jiang:2008hc,Vasquez:2004ty,Evans:1982oq</string>
1865 </dict>
1866 <dict>
1867 <key>group name</key>
1868 <string>RNEMD</string>
1869 <key>keys</key>
1870 <string>Kuang:2012fe,Tenney:2010rp,Kuang:2011ef,Muller-Plathe:1997wq,Muller-Plathe:1999ao,Shenogina:2009ix,Patel:2005zm,Stocker:2013cl,Kuang:2010if</string>
1871 </dict>
1872 </array>
1873 </plist>
1874 }}

Properties

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svn:executable *