Gravitational collapse of interstellar gas clouds is driven by self-amplifying density feedback: increasing density strengthens gravitational attraction, which compresses the gas further, which raises the density. We show that this process is exactly captured by rhodot = rho exp (lambda rho), where rho is the normalized density (rho/rhoJeans) and lambda > 0 encodes the pressure-to-gravity ratio. This is the Fₗambda class of a previous work — the unique ODE of the form udot = g (u) Phi (lambda u) whose associated function space is stable under both natural derivation operators and which admits a transcendental non-elementary linearizer, the exponential integral E1. Exploiting this exact linearization, we derive: a closed-form collapse time T*coll = E1 (lambda rho0) in units of the free-fall time tff, the full Aₙ hierarchy rhodot = rhoⁿ exp (lambda rho) modeling isothermal (n=1), adiabatic (n=2), radiation-pressure (n=3), relativistic (n=4), and naked-singularity (n=5) collapse regimes, calibration on four astrophysical objects: Barnard 68, Class 0 protostar, Ophiuchus dense core, giant molecular cloud, a PDE model of spatial cloud fragmentation (Pₗambda^+) with exact solution, producing multiple stellar formation sites simultaneously, a topological invariant Omega = pi/2 - Si (mu rho0) for Bonnor-Ebert oscillations, counting oscillation periods exactly, and a real-time collapse alert computable from radio observations. The classical Jeans criterion gives a free-fall time tff = sqrt (3pi/32G rho) independent of the feedback parameter lambda. The F lambda framework gives T* = E1 (lambda rho0), which depends explicitly on lambda and classifies collapse regime analytically.
Judicael Brindel (Fri,) studied this question.