Difference between revisions of "PhDSupervision:Dhananjay Ipparthi/Table of contents"
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=== Approaches to solve the incompatible substructure problem === |
=== Approaches to solve the incompatible substructure problem === |
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===== Self-assembly ===== |
===== Self-assembly ===== |
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| − | * TODO: Tune the magnetism of the components such that the fully formed target structures are stable, but substructures are susceptible to breakage |
+ | ** TODO: Tune the magnetism of the components such that the fully formed target structures are stable, but substructures are susceptible to breakage |
===== Changing geometry ===== |
===== Changing geometry ===== |
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| − | * [Published: PPSN] |
+ | ** [Published: PPSN] |
===== Conformational switching ===== |
===== Conformational switching ===== |
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| − | * TODO: Close to final design of components |
+ | ** TODO: Close to final design of components |
===== Use of high inertia components ===== |
===== Use of high inertia components ===== |
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| − | * Successfully conducted preliminary experiments |
+ | ** Successfully conducted preliminary experiments |
| − | * TODO: Define experiment and collect data |
+ | ** TODO: Define experiment and collect data |
| ⚫ | |||
===== Dipole codes ===== |
===== Dipole codes ===== |
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| − | * [Published: Theoretical Computer Science] |
+ | ** [Published: Theoretical Computer Science] |
| ⚫ | |||
| + | |||
=== Dynamics of aggregating / self-assembling systems === |
=== Dynamics of aggregating / self-assembling systems === |
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* Nicolas has developed visual tracking system and used it to find: |
* Nicolas has developed visual tracking system and used it to find: |
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Revision as of 14:22, 17 May 2016
Table of content of thesis
Introduction
Background
- The literature review section of my rapport d'avancement covers about 60% of work that I will cover in my doctoral thesis
Theoretical treatment of incompatible substructure problem
- SWARM2015 conference paper presents initial findings of yield predictions [published]
- Extended yield predictions journal paper [not yet published. submission deadline: 5th June, 2016]
Approaches to solve the incompatible substructure problem
Self-assembly
- TODO: Tune the magnetism of the components such that the fully formed target structures are stable, but substructures are susceptible to breakage
Changing geometry
- [Published: PPSN]
Conformational switching
- TODO: Close to final design of components
Use of high inertia components
- Successfully conducted preliminary experiments
- TODO: Define experiment and collect data
Dipole codes
- [Published: Theoretical Computer Science]
- Massimo suggested, and I agree, that I write an "approaches to the yield predictions" paper. In that paper, I would include the aforementioned approaches. [not yet published]
Dynamics of aggregating / self-assembling systems
- Nicolas has developed visual tracking system and used it to find:
- Time evolution of aggregation
- Distance distribution
- Velocity distribution
- Collaboration with Korean Institute of Science and Technology [Leon Abelmann, Tijmen Hageman, etc.]
- Found the different energy regimes for our aggregating system
- Established that outside the ballistic regime, the components perform "random walk"
- The data neatly fits into a Rayleigh distribution
- TODO: Get new camera, re-analyse data
- TODO: Write a "methodology" style paper
Conclusions
- Contribution 1: Theoretical analysis of parallel assembly vis-a-vis the incompatible substructure problem
- Contribution 2: 5 approaches to avoid the incompatible substructure problem
- Contribution 3: Study of the dynamics of aggregation / parallel assembly
