Electrical Polarization process

Placement of a pulse voltage potential (65) across Excitor plates (El!E2) (voltage zones
66/67) of Figure (3-29) as to Figure (3-26) while inhibiting and preventing electron flow within
voltage intensifier circuit (190) of Figure (3-23) causes water molecule (210) of Figure (3-27) to
separate into its component parts (released hydrogen and oxygen gases) by pulling away (utilizing
Stanley A Meyer
3-14RE: WFC Hydrogen Gas Management System
Memo WFC 422 DA
opposite attraction forces SS' and RR') its charged water molecule atoms (76n7), as illustrated in
(160) of Figure (3-26).
Stationary "positive" electrical voltage-field (66) (voltage plate El) not only attracts negative
charged oxygen atom (76) but also pulls away negative charged covalent electrons (84) from water
molecule (210). At the same time stationary "negative" electrical voltage field (67) (voltage plate E2)
attracts positive charged hydrogen atoms (77a/b). Once negative electrically charged oxygen atom (76)
is dislodged from water molecule (85), covalent bonding (sharing electrons between atoms) ceases to
exist, switching-off and disrupting electrical attraction force (qq') between unlike atoms (76/77), as
further illustrated in (160) of Figure (3-26).
Opposite polarity electrical attraction force (SS') continues to cause negative charged oxygen atom (76)
to migrate to positive voltage-plate (E1) (positive voltage zone 66); while, at the same time, opposite
polarity electrical attraction force (RR') causes positive charged hydrogen atoms (77a/b) to migrate in
the opposite direction to negative voltage-plate (E2) (negative voltage zone 67) as step-charging
voltage-wave (65) increases in voltage amplitude from several millivolts to several hundred volts during
each pulse train (65a xxx 65n) which, in application, causes water molecule (210) of Figure (3-27)
charged atoms (76/77) to elongate (increasing distance between unlike atoms 76/77) to the point where
covalent hydrogen electrons (84) of Figure (3-27) breaks away from electrostatic force (qq'). Repetitive
duplication of voltage pulse (65a xxx 65n) continues to separate or split apart other water molecules
(85a xxx 85n) which, in turns, forms hydrogen (86) and oxygen (87) gas-mixture (88) of Figure (3-24).
Dissociation of water molecule (85) by way of voltage stimulation (65) is herein called "The Electrical
Polarization Process", as illustrated in (160) of Figure (3-26).