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AntonioLao · **even number conservation -** 11-12-2007, 12:46 PM

The principle of even number conservation is a universal principle applicable to the infinitely countable numbers of space-time quanta or charges: H+ and H-. It can be demonstrated that almost all stable chemical elements conformed to this principle.

Starting with hydrogen atom: its total space charges is ( 12, 12 ). Helium is ( 38, 38 ). Lithium is ( 64, 64 ). Beryllium is ( 83, 83 ). Boron is ( 102, 102 ). Carbon is ( 114, 114 ). Nitrogen is ( 133, 133 ). Oxygen is ( 152, 252 ). Fluorine is ( 178, 178 ). Neon is ( 190, 190 ). Sodium is ( 216, 216 ). Magnesium is ( 228, 228 ). Aluminum is ( 254, 254 ). Silicon is ( 266, 266 ). Phosphorus is ( 292, 292 ). Sulfur is ( 304, 304 ). Chlorine is ( 330, 330 ). Argon is ( ( 370, 370 ). Potassium is ( 368, 368 ). Calcium is ( 380, 380 ). Scandium is ( 420, 420 ). Titanium is ( 446, 446 ). Vanadium is ( 472, 472 ). Chromium is ( 484, 484 ). Manganese is ( 510, 510 ). Iron is ( 522, 522 ). Cobalt is ( 548, 548 ), etc. It is not necessary to continue this process since at the outset it was clear that hydrogen is ( 12, 12 ) and all succeeding elements become its multiples with the exception of neutron numbers which is a multiple of ( 7, 7 ). What is important is the idea of universal even number conservation. Even though elementary particles do not conserve evenness but once they combined into neutral atoms the principle of even conservation is obeyed almost absolutely.

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AntonioLao Raider of the lost time Status: Offline Posts: 5,613 Thanks Given: 790 Thanked 184x in 178 Posts Join Date: Nov 2003 Rep Power: 80	even number conservation - 11-12-2007, 12:46 PM The principle of even number conservation is a universal principle applicable to the infinitely countable numbers of space-time quanta or charges: H+ and H-. It can be demonstrated that almost all stable chemical elements conformed to this principle. Starting with hydrogen atom: its total space charges is ( 12, 12 ). Helium is ( 38, 38 ). Lithium is ( 64, 64 ). Beryllium is ( 83, 83 ). Boron is ( 102, 102 ). Carbon is ( 114, 114 ). Nitrogen is ( 133, 133 ). Oxygen is ( 152, 252 ). Fluorine is ( 178, 178 ). Neon is ( 190, 190 ). Sodium is ( 216, 216 ). Magnesium is ( 228, 228 ). Aluminum is ( 254, 254 ). Silicon is ( 266, 266 ). Phosphorus is ( 292, 292 ). Sulfur is ( 304, 304 ). Chlorine is ( 330, 330 ). Argon is ( ( 370, 370 ). Potassium is ( 368, 368 ). Calcium is ( 380, 380 ). Scandium is ( 420, 420 ). Titanium is ( 446, 446 ). Vanadium is ( 472, 472 ). Chromium is ( 484, 484 ). Manganese is ( 510, 510 ). Iron is ( 522, 522 ). Cobalt is ( 548, 548 ), etc. It is not necessary to continue this process since at the outset it was clear that hydrogen is ( 12, 12 ) and all succeeding elements become its multiples with the exception of neutron numbers which is a multiple of ( 7, 7 ). What is important is the idea of universal even number conservation. Even though elementary particles do not conserve evenness but once they combined into neutral atoms the principle of even conservation is obeyed almost absolutely. Time independence: [∂E(g)]²=[∂F(a)×∂r(a)]·[∂F(b)×∂r(b)] and Mass independence: ¶a(t)·¶r(t)=c²