Mass-Flow Invariance of Q-Cohomology in BMN Matrix Quantum Mechanics

Abstract

We study the dependence of the dynamical supercharges of BMN matrix quantum mechanics on the mass parameter μ. Taking the μ-derivative at fixed canonical matrix variables, we show that the sixteen-component supercharge evolves by the adjoint action of a Hermitian quadratic bosonic operator K, together with the spinor-space factor iγ123. After projection to a γ123-eigenspace, this flow integrates to a finite similarity transformation. For the nilpotent component Q(μ)= Q4-(μ), one obtains Q(μ)=M(μ,μ0)Q(μ0)M(μ,μ0)-1, giving an algebraic mass-flow non-renormalization statement for the Q-cohomology. The corresponding Hilbert-space statement has an analytic qualification, parallel to Witten's argument for supersymmetric quantum mechanics: M is non-unitary and unbounded, so its action on the normalizable domain must be controlled. We formulate a small-step criterion by comparing the quadratic growth of M with the Gaussian falloff of BMN oscillator wavefunctions within each component μ>0 or μ<0. As a concrete check, we evaluate this condition in the N=2 theory, whose two vacuum sectors are built on the trivial vacuum and the irreducible fuzzy-sphere vacuum. We also compute the induced Q BPS-action on the corresponding BPS letters: in the trivial sector it agrees with the standard BMN-sector BPS-letter differential of N=4 SYM, while in the irreducible sector it vanishes.