Superfluidic space with quantised spins – Theoretical expressions for addressing the vacuum catastrophe

General relativity with its cosmological constant brought the notion of space containing internal energy. Attributing dark energy to vacuum energy density with the standard model is faced with a large mismatch. In line with super-fluidic vacuum theories on the cosmological constant, and the experimental evidence of spontaneously forming and indefinitely rotating quantum vortices in superfluidity, this work proposes the following: 1. The internal energy-pressure differentials that persist across the super-fluid like space continuum, lead to multitudes of local Planck-scale energy peaks or folds which collapse to form quantum vortices. 2. Such vortices continuously form, and over long periods gradually dissipate their kinetic energy into the continuum and deform, 3. Each of such local spinning field constitutes curl and divergent vectors as in Helmholtz decomposition, 4. The divergent vector implies an outward propagating energy from the spin, pushing the surrounding vortices apart. 5. Such discrete vortex distancing events occurring in quantum scale upon aggregation exhibit as the inflationary phenomenon - similar to Casimir effect where in oscillations of the vacuum energy fluctuation of empty space, exerting a force on a macroscopic object, causing its movement. 6. In line with ‘quantum foam’ the space continuum is at a vibratory state, implying a pulsatory bulk pressure acting on the aforesaid vortex distancing event. A theoretical model is developed, and the cosmological constant is derived as a function of the divergent energy grand sum from local spins. Time variability of the cosmological constant is arrived by incorporating vortex generation and decay rates, and the accelerated expansion is attributed to the difference between these rates, in a continuum of oscillatory energy-pressure.