Basic Principles of Spectroscopy |
From inside the book
Results 1-3 of 7
Page 270
Raymond Chang. Potential energy Table 15-1 Rare gas Ionization potential ( eV ) Spectroscopic ioniza- tion potential ( eV ) Argon 15.79 15.93 15.755 15.933 Krypton 14.05 14.69 13.99 1465 Xenon 12.17 13.49 12. 127 13.427 SOURCE : M. I. Al ...
Raymond Chang. Potential energy Table 15-1 Rare gas Ionization potential ( eV ) Spectroscopic ioniza- tion potential ( eV ) Argon 15.79 15.93 15.755 15.933 Krypton 14.05 14.69 13.99 1465 Xenon 12.17 13.49 12. 127 13.427 SOURCE : M. I. Al ...
Page 271
... ionization potential without rotational and vibra- tional changes . It is appropriate here to distinguish the terms adiabatic and vertical ionization potential . The former refers to the v = 0 → 0 transition , which corresponds to the ...
... ionization potential without rotational and vibra- tional changes . It is appropriate here to distinguish the terms adiabatic and vertical ionization potential . The former refers to the v = 0 → 0 transition , which corresponds to the ...
Page 274
Raymond Chang. example , to obtain the first , second , etc. , ionization potentials simul- taneously . The first ionization potential is defined here as the minimum energy required to remove a single electron from the highest filled ...
Raymond Chang. example , to obtain the first , second , etc. , ionization potentials simul- taneously . The first ionization potential is defined here as the minimum energy required to remove a single electron from the highest filled ...
Contents
PREFACE | 1 |
NUCLEAR QUADRUPOLE RESONANCE SPECTROSCOPY | 29 |
NUCLEAR MAGNETIC RESONANCE SPECTROSCOPY | 52 |
Copyright | |
17 other sections not shown
Other editions - View all
Common terms and phrases
absorption angular momentum applied atomic orbitals axis bands benzene bond Chap Chem chemical shift Chemistry components compounds constant coordinates diagram diatomic molecule dipole discussed Educ effect electric field electronic transition emission energy levels equation example excited fluorescence frequency given hence intensity interaction ionization potential irreducible representation laser linear lines magnetic field magnetic moment Magnetic Resonance matrices McGraw-Hill Book Company Microwave Spectroscopy molecular orbital Mössbauer Mössbauer Effect normal modes Nuclear Magnetic nuclear quadrupole nucleus obtained optically active oscillator permission phosphorescence photoelectron Phys plane point group polarized potential energy protons quantum mechanics quantum number R₂ radiation Raman selection rules shown in Fig shows solution spectra spectrometer spectrum spin-spin splitting structure studies symmetry elements symmetry operations Table technique tion triplet unpaired values vector wave function wavelength Wiley & Sons York Zeeman zero ΔΕ