purpose of which was to quantum-entangle the poured water with the water in the large
tank. In a fifth variation of the above setup, the gravity portion of the experiment was
eliminated and the water in the first and second reservoirs was combined into a closed
glass fourth-reservoir which was moved to a location more than 50 miles away from the
Dewar for temperature measurement.
Figure 2 shows a diagram of the second experimental setup. It includes: (1) a red
laser with a 50mW output and wavelengths 635nm - 675nm placed next and pointed to a
flat glass first-reservoir containing 200ml tap water sitting in room temperature for more
than a week without air exchange; (2) the calibrated pH meter and optionally the digital
thermometer placed into the middle of the said flat glass reservoir which was closed to
prevent air exchange; and (3) a round glass second-reservoir containing 100ml
concentrated HCl (30% by weight) to be placed 500cm away from the first-reservoir at a
specified time.
Experiments with the above second setup were carried out as follows: (1) prepare
the 200ml tap water and set up the experiment according Figure 2; turn on the laser so
that the laser light first passes through the first-reservoir and then gets scattered on a
nearby concrete wall, and let the instruments to stabilize for 30min before any
measurement is taken; (2) record for 10min. minute-by-minute changes of pH value and
optionally temperature of the water in the first-reservoir; and (3) place the second
reservoir containing 100ml HCl on the path of the laser light and at a distance of 500cm
from the first reservoir and record for 60min or longer instrument readings as before.
Control experiments were carried out in same steps in the absence of HCl.
Figures 3, 4 and 5 summarize the results obtained from experiments conducted
with the key setup and one batch of quantum-entangled water which were simply
bottled natural water with a shelf time of more than 90 days. Similar results were also