User talk:Anne Marie Fanger

PHOTOSYNTHESIS A quanta

- magnetic reaction

Anne Marie Fanger, Denmark Plant photosynthesis is a quanta-magnetic reaction, where the molecules necessary for the creation of  glucose are combined together directly by  light. The photosynthetic equation(5): 36 light photons 4 O2 + 6 CO2 + 12 H2O                                 C6H12O6  +   6 H2O  +   10 O2

THE MOLECULAR STRUCTURE OF THE PHOTOSYNTHETIC UNIT A cube: of 4  molecules of oxygen are attached to the magnesium atom in the chlorophyll molecule. An octahedron: A cube has 6 sides, a molecule of carbon dioxide is attached to each side forming an octahedron - a bent hexagon. 12 molecules of water are attached one to each oxygen atom of the carbon dioxide. .ELECTRON MOVEMENTS Light: photons create a magnet: 6 electrons from the 6 carbon atoms and 6 electrons from 6 oxygen atoms of the 6 molecules of carbon dioxide are send into π-orbit between the 6 carbon atoms by light photons (C electron: 650 μm, O electron: 410 μm ). The magnet: 12 electrons circulating in π-orbit creates a magnet of (12 x 3.8 eV(1))=   45.6     eV , to kick out 16 electrons from the central 4 oxygen molecules, takes                              40.054 eV  8 oxygenIII atoms are created. Light: As the excitation energy of the magnesium electron is present in the absorbtion spectrum of plants (680 μm)., the 16 electrons must be attracted one by one to the magnesium atom from where the electrons by light photons are send into π-orbit (680 μm). Light: 8 photons send 8 electrons from the 8 oxygenIII atoms into π-orbit (562 μm). GLUCOSE CREATION: 24 electrons from the central 8 oxygenI atoms circulating in π-orbit have sufficient energy,                                                    91.6  eV (1), breaking the bindings of the molecules of CO2 and H2O,, use:                              41.72  eV(8). 12 electrons stay in π-orbit binding the molecule of glucose together. EXPERIMENTAL PROOF :  ABSORBED  LIGHT  ENERGY  =    EXCITATION  ENERGY E excit. = E π –orbit benzene - E electron atom; E π –orbit benzene = 3.8 eV  (1). The energy of a light wave with the wavelength λ :                Eabs. = h  c / λ    (1) h = 4,1356672716 eV;      c = 2.99792584 x 108 m s-1;    1 eV = 8.o6554477 x 105 m-1  ( 6)

Colour of light  λ max abs. Eabs. Eexcit    E e atom      E e atom         Atom a.                                            Red                  680        1.09        1.091       21850        2.709         Magnesium Yellow              650        1.137       1.136       21645        2.664          Carbon Orange              562        1.32        1.28        20271        2.51          OxygenIII Blue                410        1.81        1.83        15868        1.967          OxygenI

(2,3,4, 7).The probability P, that the absorbed energy is not equal to the excitation energy  is  true:                     P = 0.00010094;

Literature : 1. Alonso, M. and Finn, E.J. (1968): ‘PHYSICS’ Addison Wesley Longman Ltd. 2. Duisens, L. N. M.; Amesz, J.  and Kamp, B.M. (1961): ‘Two photochemical systems in photosynthesis’. Nature Vol. 190: 510-511. 3. Emerson, R. and Lewis, C. M. (1943): The dependence of the quantum yield of Chlorella photosynthesis on wavelengths of light. American Journal of Botany 30: 165-178.4. Emerson, R., Chalmers, C. and Cederstrand, C. (1957): Some factors influencing the long wave limit of photosynthesis. Proceedings of the National Academy of Science USA 43: 133 - 143. 5.Fanger, A.M. (2003): PCT patent PA 200101654. 6. Lide, D.R. ( 1999): ‘Handbook of chemistry and physics’ CRC Press. 7.Moore, C.E. (1971): Nat. Stand. Ref. Data Ser, Nat. Bur Stan  35, V.I   8:Thauer, R.K., Jungerman, K. and Decker, K.  (1977):   Energy conservation in  chemotrophic anaerobic bacteria. Bact Rev 41: 100 – 180                                              Amou:     17 juni  2011          Anne Marie Fanger