In weak measurement thought experiment, an ensemble consists of M quantum particles and N states. We observe that separability of the particles is lost, and hence we have fuzzy occupation numbers for the particles in the ensemble. Without sharply measuring each particle state, quantum interferences add extra possible configurations of the ensemble, this explains the Quantum Pigeonhole Principle. This principle adds more entropy to the system; hence the particles seem to have a new kind of correlations emergent from particles not having a single, well-defined state. We formulated the Quantum Pigeonhole Principle in the language of abstract Hilbert spaces, then generalized it to systems consisting of mixed states. This insight into the fundamentals of quantum statistical mechanics could help us understand the interpretation of quantum mechanics more deeply, and possibly have implication on quantum computing and information theory. In this study, we present a multifunctional peptide based on the neutrophil immune defense molecule, CAP37, has antibacterial and wound-healing properties for Unconstrained Optimization Statistical Mechanics for Weak Measurements and Quantum Inseparability Novel procedure Computational Scaffolding on tumorigenic stem cell bacterial infected hybrids for the in silico rescaffolding and side-chain optimization on the neutrophil immune defense CAP37 protein.
Quantum Computing, Copenhagen Interpretation, Quantum Pigeonhole Principle, Quantum Correlation, Information Theory, Quantum Statistical Mechanics, Weak Measurement, Quantum Measurement, Post Selection1, A multifunctional peptide based on the neutrophil immune defense molecule, CAP37, antibacterial; wound-healing; Unconstrained Optimization; Statistical Mechanics; Weak Measurements; Quantum Inseparability; Novel Computational Scaffolding; tumorigenic; stem cell bacterial; infected hybrids; in silico rescaffolding; side-chain; neutrophil immune; defense CAP37 protein;