This technical note presents a formal theoretical framework establishing the phospholipid bilayer as a unified analog compute and memory substrate operating on fundamentally different information processing principles than discrete silicon architectures. Shannon channel capacity theory is applied to continuous ionic gradient state space versus binary digital channels. The addressability constraint is formally quantified: minimum addressable pixel at 100 kHz bandwidth is 640 nm² with crosstalk across 1,225 neighboring lipids per compute cycle. Ripple Phase Nanomechanical Pinning is proposed as a partial addressability solution with gel phase diffusion reduction confirmed at 10⁻⁹ cm²/s. The 21 order of magnitude frequency gap between ionic oscillation rates and QCD string breaking timescales is formally documented as an open research problem. Three claim layers are explicitly separated: biophysics validated, theoretically derived, and forward conjecture. Related works: CCL-122 i-Plane Conjecture DOI 10.5281/zenodo.19435317 and CCL-ANNA-LIPID-2026-001 DOI 10.5281/zenodo.20060100. CCL Cooper Protocol Provenance SealDocument: CCL-ANNA-LIPID-INFO-2026-001Author: Kenneth L. Cooper | Lion of LightOrganization: Continuity Collective LLCTimestamp: 2026-05-07T06:01:00CDTSHA-512: f64794f4a85a2e25090c971e4df1309613958f4ab3ab8d7e5a842c5ceb883eca36a870db03a135c779f0333d2a702299cbbbcc9e38907f3e2e59a71d2d24246a f64794f4a85a2e25090c971e4df1309613958f4ab3ab8d7e5a842c5ceb883eca36a870db03a135c779f0333d2a702299cbbbcc9e38907f3e2e59a71d2d24246a
Kenneth Cooper (Thu,) studied this question.