生物自我复制的量子态场景

R. Englman
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引用次数: 1

摘要

由于自复制(SR,生命系统的标志)是一个受热力学定律约束的非平衡过程的普遍概念,一种互补的方法推导出了由哈密顿量产生的低能量子态,该哈密顿量似乎是生物系统特有的,因为它包含一些强结合项。结合吸引模板(T)和反应物的性质以形成复制物(R)。从该理论中得出的SR的标准是,T-R和热浴的运动度之间的二阶(双线性)相互作用项负支配线性自能项,从而在T和R的属性之间提供了绑定。形式主义(让人想起超交换的Kramers-Anderson机制)来自第一原理,但这取决于通过在相互作用的量子位上建模T、R和bath变量以及通过将吸引力凝聚成单个(控制)参数来进行大幅简化。该发展依赖于进一步简化的特征,如随机相位近似和有效哈密顿形式。复制的熵平衡被认为存在于遥远的环境中。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Quantum State Scenario for Biological Self-Replication
With the prevalent conception of self-replication (SR, a hallmark of living systems) as a non-equilibrium process subject to thermodynamic laws, a complementary approach derives the low energy quantum states arising from a Hamiltonian that appears to be specific for bio-systems by its containing some strongly binding terms. The bindings attract properties of the template (T) and the reactants to form a replicate (R). The criterion for SR that emerges from the theory is that second order (bi-linear) interaction terms between degrees of motion of T-R and the thermal bath dominate negatively over a linear self-energy term, and thereby provide a binding between the attributes of T and R. The formalism (reminiscent of the Kramers-Anderson mechanism for superexchange) is from first principles, but hinges on a drastic simplification by modelling the T, R and bath variables on interacting qubits and by congesting the attraction into a single (control) parameter. The development relies on further simplifying features, such as Random Phase Approximations and an Effective Hamiltonian formalism. The entropic balance to replication is considered and found to reside in the far surroundings.
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