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\chapter{\label{chapt:conclusion}CONCLUSION} |
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This dissertation has presented the work and research accomplished |
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over the course of the past five years. Chapt.~\ref{chapt:RSA} |
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illustrated the application of statistical mechanical principles to |
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the solution of an experimental problem. Given a relatively simple |
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model, could the differences in experimental coverage be accounted |
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for? By utilizing Monte Carlo modeling methods, I wrote several |
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simulations that provided a clear explanation for the majority of |
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the experimental evidence. Namely, that overlapping, or |
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interdigitating molecules were responsible for the high surface |
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coverage of the ``umbrella'' silicon phthalocyanines, while the |
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``octopus'' molecules, which do not overlap, have a much lower |
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coverage. |
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Chapt.~\ref{chapt:oopse} presented the work necessary to the |
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solution of more complex research problems. It became clear, after |
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the work on the RSA simulations, that even simple simulations can |
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take a great deal of programming. If I were to simulate the bilayer |
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systems using a coarse-grained model, a sophisticated molecular |
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modeling program was required. After examining the options available |
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at the time, writing an advanced simulation program was the only |
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realistic solution. |
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Working with my lab-mates, I have developed our simulation program |
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({\sc oopse}) to the point where it is capable carrying out many |
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unique simulations. It properly integrates rigid body dynamics. It |
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has the capability to model dipoles rather than point charges only; |
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and is therefore able to integrate larger systems for longer times |
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than any other current modeling package. It can use the MPI |
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interface to calculate the long range forces across multiple |
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processors. And lastly, it is open source, so that other scientists |
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may use the code and contribute back to the project and enhance the |
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program. |
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Lastly Chapt.~\ref{chapt:lipid} presented the research that became |
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the main design goal of {\sc oopse}. The lipid model was under |
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continual development while {\sc oopse} was being written. In fact |
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many of the integration ensembles in {\sc oopse} were specifically |
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written to continue development of the lipid model. The set of |
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simulations presented in the chapter have shown that the model is |
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capable of spontaneously forming bilayers. It also explored the |
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properties of the bilayers over a range of temperatures. Further |
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extensions to the model will likely include exploration of how head |
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group dipole strength and varying chain configurations (one chain |
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versus two chains, etc.) affect the structure and dynamics of the |
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lipid bilayer. However, at this point there are many questions that |
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can now be explored with this model such as how do small molecules |
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include themselves, and diffuse through the bilayer? Or what are the |
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characteristic events that lead to the formation of special lipid |
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phases (i.e.~the ripple phase)? It is my hope that my contributions |
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to this research will make it possible to answer these important |
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questions and many others. |