计算和化学中的自组织:回到 AlChemy。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-09-01 DOI:10.1063/5.0207358
Cole Mathis, Devansh Patel, Westley Weimer, Stephanie Forrest
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引用次数: 0

摘要

复杂的自适应系统(如生命)是如何从简单的组成部分中产生的?20 世纪 90 年代,沃尔特-方塔纳和利奥-布斯提出了一种新颖的建模方法来解决这个问题,该方法基于一个被称为λ微积分的计算形式模型。该模型展示了简单的规则如何嵌入组合性巨大的可能性空间,从而产生复杂、动态稳定的组织,让人联想到生化反应网络。在这里,我们重新审视了这个在过去 30 年中一直未得到充分研究的经典模型,它被称为 AlChemy。我们重现了原始结果,并利用当今更强大的计算资源研究了这些结果的稳健性。我们的分析揭示了该系统的几个意想不到的特征,展示了动态鲁棒性和脆弱性的惊人组合。具体来说,我们发现复杂、稳定的组织比以前预期的出现得更频繁,这些组织对坍缩到琐碎的固定点很稳健,但这些稳定的组织不能轻易地组合成更高阶的实体。我们还研究了模型中使用的随机生成器的作用,描述了两个随机表达生成器产生的对象的初始分布及其对结果的影响。最后,我们提供了一个构造性证明,说明基于类型化 λ 微积分的模型扩展如何能够模拟任何可能的化学反应网络中任意状态之间的转换,从而表明 AlChemy 与化学反应网络之间的具体联系。最后,我们将讨论 AlChemy 在现代编程语言自组织和生命起源定量方法中的可能应用。
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Self-organization in computation and chemistry: Return to AlChemy.

How do complex adaptive systems, such as life, emerge from simple constituent parts? In the 1990s, Walter Fontana and Leo Buss proposed a novel modeling approach to this question, based on a formal model of computation known as the λ calculus. The model demonstrated how simple rules, embedded in a combinatorially large space of possibilities, could yield complex, dynamically stable organizations, reminiscent of biochemical reaction networks. Here, we revisit this classic model, called AlChemy, which has been understudied over the past 30 years. We reproduce the original results and study the robustness of those results using the greater computing resources available today. Our analysis reveals several unanticipated features of the system, demonstrating a surprising mix of dynamical robustness and fragility. Specifically, we find that complex, stable organizations emerge more frequently than previously expected, that these organizations are robust against collapse into trivial fixed points, but that these stable organizations cannot be easily combined into higher order entities. We also study the role played by the random generators used in the model, characterizing the initial distribution of objects produced by two random expression generators, and their consequences on the results. Finally, we provide a constructive proof that shows how an extension of the model, based on the typed λ calculus, could simulate transitions between arbitrary states in any possible chemical reaction network, thus indicating a concrete connection between AlChemy and chemical reaction networks. We conclude with a discussion of possible applications of AlChemy to self-organization in modern programming languages and quantitative approaches to the origin of life.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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