We study the following fundamental questions in DNA based self-assembly and nanorobotics:
How to control errors in self-assembly? How to construct complex nanoscale objects in simpler ways? How to transport nanoscale objects in programmable manner?Fault tolerance in self-assembly: Fault tolerant self-assembly is important for nanofabrication and nanocomputing applications. It is desirable to design compact error-resilient schemes that do not result in the increase in the original size of the assemblies. We present a comprehensive theory of compact error-resilient schemes for algorithmic self-assembly in two and three dimensions, and discuss the limitations and capabilities of redundancy based
compact error correction schemes.New and powerful self-assembly model:
We develop a reversible self-assembly model in which the glue strength between two juxtaposed tiles is a function of the time they have been in neighboring positions. Under our time-dependent glue model, we can rigorously study and demonstrate catalysis and self-replication in the tile assembly. We can assemble thin rectangles of size k×N using O(logN/loglogN) types of tiles in our model.Modeling DNA based Nanorobotical Devices: We design a framework for a discrete event simulator for DNA based nanorobotical systems. It has two major components: a physical model and a kinetic model. The physical model captures the conformational changes in molecules, molecular motions and molecular collisions. The kinetic model
governs the modeling of various reactions in a DNA nanorobotical systems including hybridization, dehybridization and strand displacement.DNA-based molecular devices using DNAzyme: We design a class of nanodevices that are autonomous, programmable, and require no protein enzymes. Our DNAzyme based designs include (1) DNAzyme FSA, a finite state automata device , (2) DNAzyme router for programmable routing of nanostructures on two-dimensional DNA addressable lattice, and (3) DNAzyme doctor, a medical-related application that respond to the under-expression or over-expression of various RNAs, by releasing an RNA.Nanomotor Powered by Polymerase: We, for the first time, attempt to harness the
mechanical energy of a polymerase φ29 to construct a polymerase based nanomotor that pushes a cargo on a DNA track. Polymerase based nanomotor has advantage of high speeds of polymerase. / Dissertation
| Identifer | oai:union.ndltd.org:DUKE/oai:dukespace.lib.duke.edu:10161/443 |
| Date | 10 December 2007 |
| Creators | Sahu, Sudheer |
| Contributors | Reif, John H |
| Source Sets | Duke University |
| Language | en_US |
| Detected Language | English |
| Type | Dissertation |
| Format | 1068011 bytes, application/pdf |
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