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is conserved, as if the heat or lack of it in manipulation reservoir is directly available to
the water in the detecting reservoir.
Third, when water in manipulation reservoir is manipulated though extreme
cooling, heating or mixing with large quantum-entangled mass, e.g., water, such that the
quantum entanglement of the water under manipulation with its local environment
changes, the weight of the water in the detecting reservoir also changes under the non-
local influence of the manipulation reservoir mediated through quantum entanglement
so that, it is hereby predicted, that the global gravitational energy/potential is conserved.
We suggest here that the said quantum entities inside water are likely nuclear
spins for the reasons discussed below. Water contains vast numbers of nuclear spins
carried by 1H. These spins form complex intra- and inter-molecular networks through
various intra-molecular J- and dipolar couplings and both short- and long-range
intermolecular dipolar couplings. Further, nuclear spins have relatively long relaxation
times after excitations8. Thus, when a nematic liquid crystal is irradiated with multi-
frequency pulse magnetic fields, its 1H spins can form long-lived intra-molecular
quantum coherence with entanglement for information storage9. Long-lived (~ .05 ms)
entanglement of two macroscopic electron spin ensembles in room temperature has also
been achieved1. Furthermore, spin is a fundamental quantum process and was shown to
be responsible for the quantum effects in both Hestenes and Bohmian quantum
mechanics10, 11. Thus, we suggest that quantum-entangled nuclear spins and/or electron
spins are likely the mediators of all observed non-local effects reported here4.
Several important conclusions and implications can be drawn from our findings.
First, we have realized non-local signalling using three different physical observables,
pH value, temperature and gravity. Second, we have shown that the temperature of
water in a detecting reservoir quantum-entangled with water in a remote reservoir can