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Updated: May 22, 2025

Phase Diagram Characterization Using Magnetic Beads as Liquid Carriers
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Phase separation in active binary mixtures with chemical reaction.

Sayantan Mondal1, Prasenjit Das1

  • 1Department of Physical Sciences, Indian Institute of Science Education and Research - Mohali, Knowledge City, Sector 81, SAS Nagar 140306, Punjab, India. prasenjit.das@iisermohali.ac.in.

Soft Matter
|May 1, 2025
PubMed
Summary
This summary is machine-generated.

Motility-induced phase separation (MIPS) in active binary mixtures with a chemical reaction shows that component activity and reaction rate control droplet formation. Domain size grows diffusively and reaches a steady state dependent on the reaction rate.

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Area of Science:

  • Soft Matter Physics
  • Chemical Physics
  • Non-equilibrium Systems

Background:

  • Active matter systems exhibit unique collective behaviors not seen in equilibrium systems.
  • Motility-induced phase separation (MIPS) is a key phenomenon in active matter, leading to self-organization.
  • The interplay between activity, interactions, and chemical reactions in active mixtures is not fully understood.

Purpose of the Study:

  • To investigate the influence of a reversible chemical reaction (A ⇌ B) on MIPS in active binary mixtures.
  • To determine how reaction rate and relative component activity affect emergent morphologies and domain growth dynamics.
  • To characterize the steady-state domain structures and their scaling relationships.

Main Methods:

  • Phenomenological incorporation of a chemical reaction rate (Γ) into existing MIPS evolution equations for density fields.
  • Analysis of steady-state domain morphologies based on reaction rate (Γ) and relative activity (Δ).
  • Calculation of equal-time correlation functions (C(r,t)) and structure factors (S(k,t)) to characterize domain morphology.
  • Investigation of the time evolution of average domain size (L(t)) and its steady-state value (Lss).

Main Results:

  • Steady-state domain morphologies are dependent on the reaction rate (Γ) and relative activity (Δ).
  • For sufficiently high Γ and Δ ≠ 1, the more active component forms droplet-like structures.
  • Domain growth follows L(t) ∼ t^(1/3) (diffusive growth) before reaching a steady state.
  • The steady-state domain size exhibits a scaling relation Lss ∼ Γ^(-1/4), independent of Δ.

Conclusions:

  • Chemical reactions significantly alter MIPS in active binary mixtures, enabling control over emergent structures.
  • The reaction rate is a crucial parameter determining steady-state morphology and domain size.
  • The observed scaling laws provide fundamental insights into the dynamics of active phase separation under reaction conditions.