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Surface Excess Energy as a Unifying Thermodynamic Framework for Active Diffusion.

Andrés Arango-Restrepo1, J Miguel Rubi1,2

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Summary
This summary is machine-generated.

Chemical reactions boost particle diffusion beyond thermal limits by generating surface energy and stresses. This active diffusivity in catalytic particles offers new ways to control synthetic active matter mobility.

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Area of Science:

  • Soft Matter Physics
  • Chemical Engineering
  • Materials Science

Background:

  • Particle motion is usually driven by external gradients (chemical, electric, thermal).
  • Chemical reactions can increase particle diffusion (active diffusivity) without external gradients, but mechanisms are not fully understood.
  • Existing models like self-diffusiophoresis don't fully explain experimental observations.

Purpose of the Study:

  • Investigate the fundamental mechanisms behind active diffusivity in catalytic Janus particles in reactive media.
  • Quantify the contribution of interfacial reactions to particle motion beyond classical thermal limits.
  • Develop a framework to explain and predict active diffusivity trends.

Main Methods:

  • Studied catalytic Janus particles in reactive solutions without imposed gradients.
  • Utilized both dissipative and nondissipative theoretical approaches.
  • Assumed the surrounding aqueous bath remains near thermodynamic equilibrium.

Main Results:

  • Interfacial chemical reactions generate excess surface energy and sustained interfacial stresses.
  • These interfacial phenomena supplement thermal energy, leading to diffusion beyond the classical thermal limit.
  • The developed framework accurately reproduces experimental trends, including non-monotonic diffusivity versus activity, for Janus particles and enzyme-driven vesicles.

Conclusions:

  • Chemical reactions are a direct source of surface excess energy and surface-tension gradients, driving active diffusivity.
  • This provides a new understanding of active matter mobility beyond phoretic effects.
  • Offers design principles for controlling the motion of synthetic active particles.