Repeatedly readable state, spontaneous collapse, and quantum/classical boundary

Abstract

We propose a model to identify the quantum/classical boundary. The model introduces a spontaneous collapse of state superposition: ddt ij =-i[H,]ij-ij/τij. Different from other collapse models, the collapsing scale τij here does not contain a universal parameter, but is specified by the two states | i and | j: If each state is in principle repeatedly readable (typically by a QND measurement), then τij is the potentially needed measuring time to discriminate the two states, and the collapse occurs spontaneously without any actual monitoring. Otherwise, τij=∞, which means no collapse and everlasting superposition. This happens if one state is not repeatedly readable, or if the two states cannot possibly be discriminated in a particular circumstance (for example in the Rabi oscillation). Detailed analysis shows that for a "trapped Schr\"odinger's cat", the superposition of | here and | there is forbidden if E D 4π c, and allowed if E D 4π c, where D is the trap separation and E is the energy gap, which can be estimated with M v2. The model also constrains a "free Schr\"odinger's cat" to display double-slit interference if pθ D 8, where p= Mv, θ is the angle spanned by the two trajectories, and D is the slit separation. In contrast, this model sets no limit on the coherent length of massless photon, thus the arm of a Michelson interferometer can be arbitrarily long. The spontaneous collapse which we propose can occur for an isolated system, and parallels the decoherence induced by interaction with environment.