Resolution of Loschmidts Paradox via Geometric Constraints on Information Accessibility
- URL: http://arxiv.org/abs/2511.03843v1
- Date: Wed, 05 Nov 2025 20:23:58 GMT
- Title: Resolution of Loschmidts Paradox via Geometric Constraints on Information Accessibility
- Authors: Ira Wolfson,
- Abstract summary: We resolve Loschmidt's paradox -- the apparent contradiction between time-reversible microscopic dynamics and irreversible macroscopic evolution.<n>The resolution: entropy increases not because dynamics are asymmetric, but because information accessibility is geometrically bounded.<n>This framework preserves microscopic time-reversal symmetry, requires no special initial conditions or Past Hypothesis, and extends to quantum systems.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: We resolve Loschmidt's paradox -- the apparent contradiction between time-reversible microscopic dynamics and irreversible macroscopic evolution -- including the long-standing puzzle of the thermodynamic arrow of time. The resolution: entropy increases not because dynamics are asymmetric, but because information accessibility is geometrically bounded. For Hamiltonian systems (conservative dynamics), Lyapunov exponents come in positive-negative pairs ($\{\lambda_i, -\lambda_i\}$) due to symplectic structure. Under time reversal these pairs flip ($\lambda_i \to -\lambda_i$), but stable manifolds contract below quantum resolution $\lambda = \hbar/\sqrt{mk_BT}$, becoming physically indistinguishable. We always observe only unstable manifolds where trajectories diverge. Hence information loss proceeds at the same rate $h_{KS} = \frac{1}{2}\sum_{\text{all } i}|\lambda_i|$ in both time directions, resolving the arrow of time: ``forward'' simply means ``where we observe expansion,'' which is universal because stable manifolds always contract below measurability. Quantitatively, for N$_2$ gas at STP with conservative estimates ($h_{KS} \sim 10^{10}$ s$^{-1}$), time reversal at $t = 1$ nanosecond requires momentum precision $\sim 10^{-13}$ times quantum limits -- geometrically impossible. At macroscopic times, the precision requirement becomes $\sim 10^{-10^{10}}$ times quantum limits. This framework preserves microscopic time-reversal symmetry, requires no special initial conditions or Past Hypothesis, and extends to quantum systems (OTOCs) and black hole thermodynamics.
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