近年来，有关生物分子通过液-液相分离机制进行组织定位、功能调控的研究发展迅速。相分离产生的聚集体在众多细胞活动事件中发挥了关键作用。这些聚集体的生物功能是以相分离的物理化学性质为基础的。本文将从相分离聚集体的基本性质、相图、微观结构，相分离的统计热力学、实验和分子模拟研究等方面阐释相分离物理化学机制研究相关进展。对于生物分子相分离的重要功能体系进行了列举和归纳，收集了相分离研究的模式体系，探讨了生物分子相分离的生物功能同物理化学机制之间的关系，总结了生物分子相分离的调控机制和调控分子的设计方法，并对生物分子相分离物理化学机制研究的未来发展方向进行了展望。
The discoveries about the functions of biomolecular liquid-liquid phase separation in cell have been increased rapidly in the past decade. Condensates produced by phase separation play key roles in many cellular curial events. These biological functions are based on the physicochemical properties of phase separation. This review discusses the recent progress in understanding the physical and chemical mechanisms of biological liquid-liquid phase separation. (1) We summarized the basic properties and experimental characterization methods of phase separation droplets, including the morphology, fusion, and wetting, along with the dynamic properties of molecules in droplets, which are usually described by diffusion coefficients or viscosity and permeability. (2) We discussed the conditions affecting the liquid-liquid phase separation of biological molecules, including concentration, temperature, ionic strength, pH, and crowding effects. A database for liquid-liquid phase separation, LLPSDB, was introduced, and three types of nucleic acid concentration effects on the phase separation of protein molecules are discussed. These effects depend on the relative interaction strengths of protein-nucleic acid and protein-protein interactions. The major driving force of phase separation is multivalent interactions, and molecular flexibility is necessary for the dynamic properties. We summarized the diverse sources of multivalence, including multiple tandem repetitive domains, regular oligomerization, low-complexity domains (usually intrinsically disordered with repeat motifs for binding), and nucleic acid molecules via the main chain phosphates or repeat sequences. (3) We reviewed the statistical thermodynamics theories for describing the macromolecular liquid-liquid separation, including the Flory-Huggins theory, Overbeek-Voorn correction, random phase approximation method, and field theory simulation method. We discussed the experimental and simulation methods for studying the physiochemical mechanism of liquid-liquid phase separation. Model systems with simplified sequences for experimental studies were listed, including systems for studying the effects of charge properties, residue types, sequence length, and other properties. Molecular simulation methods can provide detailed