Andrew Winslow scite author profile

We prove a negative result on the power of a model of algorithmic self-assembly for which finding general techniques and results has been notoriously difficult. Specifically, we prove that Winfree's abstract Tile Assembly Model is not intrinsically universal when restricted to use noncooperative tile binding. This stands in stark contrast to the recent result that the abstract Tile Assembly Model is indeed intrinsically universal when cooperative binding is used (FOCS 2012). Noncooperative self-assembly, also known as "temperature 1", is where all tiles bind to each other if they match on at least one side. On the other hand, cooperative self-assembly requires that some tiles bind on at least two sides.Our result shows that the change from non-cooperative to cooperative binding qualitatively improves the range of dynamics and behaviors found in these models of nanoscale self-assembly. The result holds in both two and three dimensions; the latter being quite surprising given that threedimensional noncooperative tile assembly systems simulate Turing machines. This shows that Turing universal behavior in self-assembly does not imply the ability to simulate all algorithmic self-assembly processes. In addition to the negative result, we exhibit a three-dimensional noncooperative self-assembly tile set capable of simulating any twodimensional noncooperative self-assembly system. This tile

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Association Reactions for Poly(alkylene Oxides) and Polymeric Poly(carboxylic Acids)

Smith¹,

Winslow²,

Petersen³

1959

Ind. Eng. Chem.

174

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One Tile to Rule Them All: Simulating Any Turing Machine, Tile Assembly System, or Tiling System with a Single Puzzle Piece

Demaine¹,

Demaine²,

Fekete³

et al. 2012

Preprint

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In this paper we explore the power of tile self-assembly models that extend the well-studied abstract Tile Assembly Model (aTAM) by permitting tiles of shapes beyond unit squares. Our main result shows the surprising fact that any aTAM system, consisting of many different tile types, can be simulated by a single tile type of a general shape. As a consequence, we obtain a single universal tile type of a single (constant-size) shape that serves as a "universal tile machine": the single universal tile type can simulate any desired aTAM system when given a single seed assembly that encodes the desired aTAM system. We also show how to adapt this result to convert any of a variety of plane tiling systems (such as Wang tiles) into a "nearly" plane tiling system with a single tile (but with small gaps between the tiles). All of these results rely on the ability to both rotate and translate tiles; by contrast, we show that a single nonrotatable tile, of arbitrary shape, can produce assemblies which either grow infinitely or cannot grow at all, implying drastically limited computational power. On the positive side, we

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Intrinsic universality in tile self-assembly requires cooperation

Meunier¹,

Patitz²,

Summers³

et al. 2013

Preprint

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One Tile to Rule Them All: Simulating Any Tile Assembly System with a Single Universal Tile

Demaine

Fekete

et al. 2014

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Andrew Winslow

Intrinsic universality in tile self-assembly requires cooperation

Association Reactions for Poly(alkylene Oxides) and Polymeric Poly(carboxylic Acids)

One Tile to Rule Them All: Simulating Any Turing Machine, Tile Assembly System, or Tiling System with a Single Puzzle Piece

Intrinsic universality in tile self-assembly requires cooperation

One Tile to Rule Them All: Simulating Any Tile Assembly System with a Single Universal Tile

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