论文信息 - Negative Interactions in Irreversible Self-assembly

Negative Interactions in Irreversible Self-assembly

This paper explores the use of negative (i.e., repulsive) interactions in the abstract Tile Assembly Model defined by Winfree. Winfree in his Ph.D. thesis postulated negative interactions to be physically plausible, and Reif, Sahu, and Yin studied them in the context of reversible attachment operations. We investigate the power of negative interactions with irreversible attachments, and we achieve two main results. Our first result is an impossibility theorem: after t steps of assembly, Ω(t) tiles will be forever bound to an assembly, unable to detach. Thus negative glue strengths do not afford unlimited power to reuse tiles. Our second result is a positive one: we construct a set of tiles that can simulate an s-space-bounded, t-time-bounded Turing machine, while ensuring that no intermediate assembly grows larger than O(s), rather than O(s⋅t) as required by the standard Turing machine simulation with tiles. In addition to the space-bounded Turing machine simulation, we show another example application of negative glues: reducing the number of tile types required to assemble “thin” (n×o(logn/loglogn)) rectangles.

[1] Erik Winfree,et al. The program-size complexity of self-assembled squares (extended abstract) , 2000, STOC '00.

[2] Ming-Yang Kao,et al. Complexities for generalized models of self-assembly , 2004, SODA '04.

[3] Sudheer Sahu,et al. Complexity of graph self-assembly in accretive systems and self-destructible systems , 2011, Theor. Comput. Sci..

[4] Lila Kari,et al. Negative Interactions in Irreversible Self-assembly , 2010, DNA.

[5] Hao Wang,et al. Proving theorems by pattern recognition I , 1960, Commun. ACM.

[6] Shing-Tung Yau,et al. On the proof of the positive mass conjecture in general relativity , 1979 .

[7] Matthew Cook,et al. Computation with finite stochastic chemical reaction networks , 2008, Natural Computing.

[8] Hao Wang. Proving theorems by pattern recognition — II , 1961 .

[9] Xin-She Yang,et al. Introduction to Algorithms , 2021, Nature-Inspired Optimization Algorithms.

[10] Jack H. Lutz,et al. Random Number Selection in Self-assembly , 2009, UC.

[11] Sudheer Sahu,et al. Complexity of graph self-assembly in accretive systems and self-destructible systems , 2005, Theor. Comput. Sci..

[12] M. Sahani,et al. Algorithmic Self-Assembly of DNA , 2006 .

[13] N. Seeman. Nucleic acid junctions and lattices. , 1982, Journal of theoretical biology.

[14] Matthew J. Patitz,et al. Exact Shapes and Turing Universality at Temperature 1 with a Single Negative Glue , 2011, DNA.