Part I: Foundations

Boundary Formation

Introduction

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Boundary Formation

Among the dissipative structures that emerge, a particularly important class involves spatial or functional boundaries that separate an “inside” from an “outside.”

A boundary $\partial\Omega$ in a driven system is emergent if it satisfies four conditions:

It arises spontaneously from the dynamics (not imposed externally)
It creates a region $\Omega$ (the “inside”) with dynamics partially decoupled from the exterior
It is actively maintained by the system’s dissipative processes
It enables gradients across itself that would otherwise equilibrate

The canonical example is the lipid bilayer membrane in aqueous solution. Given appropriate concentrations of amphiphilic molecules and energy input, membranes form spontaneously because they represent a low-free-energy configuration. Once formed, they:

Separate internal chemical concentrations from external
Enable maintenance of ion gradients, pH differences, etc.
Provide a substrate for embedded machinery (channels, pumps, receptors)
Must be actively maintained against degradation

Empirical Grounding

Lipid Bilayer Self-Assembly: Spontaneous boundary formation from amphiphilic molecules.

Key thermodynamic facts:

Critical micelle concentration (CMC) for phospholipids: $\sim 10^{-10}$ M
Bilayer formation is entropically driven (releases ordered water from hydrophobic surfaces)
Once formed, bilayers spontaneously close into vesicles (no free edges)
Membrane maintains $\sim$ 70 mV potential difference across 5 nm $\Rightarrow$ field strength $\sim 10^7$ V/m

This exemplifies emergent boundary formation: arising spontaneously, creating inside/outside distinction, actively maintained, enabling gradients.

Historical Context

The recognition that membranes self-assemble was a key insight linking physics to biology:

1925: Gorter \& Grendel estimate bilayer structure from lipid/surface-area ratio
1935: Danielli \& Davson propose protein-lipid sandwich model
1972: Singer \& Nicolson’s fluid mosaic model (still current)
1970s–80s: Lipid vesicle (liposome) research shows spontaneous membrane formation

The membrane is the minimal instance of “self” in biology: a dissipative structure that creates the inside/outside distinction necessary for all subsequent organization.

Boundaries appear because they stabilize coarse-grained state variables. The emergence of bounded systems—entities with an inside and an outside—is a generic feature of driven nonlinear systems, not a special case requiring explanation.