Physical Chemistry and Its Biological ApplicationsPhysical Chemistry and Its Biological Applications ... |
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Page 290
... orbitals . The molecular orbital is occupied by the two available electrons , one from each atom , and in order that the two electrons can be in the same orbital , their spins must be opposite ; consequently , the total spin of the ...
... orbitals . The molecular orbital is occupied by the two available electrons , one from each atom , and in order that the two electrons can be in the same orbital , their spins must be opposite ; consequently , the total spin of the ...
Page 291
... orbital of the sort that would have to be occupied in an He , molecule , is termed an antibonding orbital and is designated by attaching an asterisk to its symbol . In an imaginary cross section through either the bonding orbital or the ...
... orbital of the sort that would have to be occupied in an He , molecule , is termed an antibonding orbital and is designated by attaching an asterisk to its symbol . In an imaginary cross section through either the bonding orbital or the ...
Page 301
... orbitals , and con- sequently electrons in the orbital are delocalized from one end of the carbon skeleton to the other . Energy increases with the number of nodal surfaces , the two antibonding orbitals having two and three nodes ...
... orbitals , and con- sequently electrons in the orbital are delocalized from one end of the carbon skeleton to the other . Energy increases with the number of nodal surfaces , the two antibonding orbitals having two and three nodes ...
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absorption acid adsorbed adsorption amino amount behavior benzene Calculate carbon carboxyl cell chain charge Chem chemical chemical shift chloride cm³ coefficient complex components concentration containing corresponding curve described diagram dipole dissociation distance effect electric electrolyte electron energy change enthalpy entropy enzyme equal equation equilibrium constant example force free energy frequency function H₂O heat hydrogen atom hydrogen bonds increase interaction ionic ionization k₁ k₂ kcal kcal/mol kinetic magnetic field magnitude material measured membrane mixture molar mole fraction molecular weight molecules nuclei occurs orbital osmotic pressure oxidation oxygen particles polar potential protein proton quantum number radiation rate constant ratio reactant reaction represented resonance rotation sample shown in Figure sodium solid solubility solvent species spectrum spin structure substance sucrose surface tension temperature tion titration torr transition triplet tube vapor pressure velocity vibrational viscosity volume wavelength zero