Dynamical method ENDOR

A review of the Journal of Physical Chemistry A, volume 110, issues 6 and 7, reveals that computational chemistry plays a major or supporting role in the majority of papers. Computational tools include use of large Gaussian basis sets and density functional theory, molecular mechanics, and molecular dynamics. There were quantum chemistry studies of complex reaction schemes to create detailed reaction potential energy surfaces/maps, molecular mechanics and molecular dynamics studies of larger chemical systems, and conformational analysis studies. Spectroscopic methods included photoelectron spectroscopy, microwave spectroscopy circular dichroism, IR, UV-vis, EPR, ENDOR, and ENDOR induced EPR. The kinetics papers focused on elucidation of complex mechanisms and potential energy reaction coordinate surfaces. [Pg.178]

Electron spin resonance (ESR) measures the absorption spectra associated with the energy states produced from the ground state by interaction with the magnetic field. This review deals with the theory of these states, their description by a spin Hamiltonian and the transitions between these states induced by electromagnetic radiation. The dynamics of these transitions (spin-lattice relaxation times, etc.) are not considered. Also omitted are discussions of other methods of measuring spin Hamiltonian parameters such as nuclear magnetic resonance (NMR) and electron nuclear double resonance (ENDOR), although results obtained by these methods are included in Sec. VI. [Pg.90]

There are many experimental techniques for the determination of the Spin-Hamiltonian parameters g, Ux, J. D, E. Often applied are Electron Paramagnetic or Spin Resonance (EPR, ESR), Electron Nuclear Double Resonance (ENDOR) or Triple Resonance, Electron-Electron Double Resonance (ELDOR), Nuclear Magnetic Resonance (NMR), occasionally utilizing effects of Chemically Induced Dynamic Nuclear Polarization (CIDNP), Optical Detections of Magnetic Resonance (ODMR) or Microwave Optical Double Resonance (MODR), Laser Magnetic Resonance (LMR), Atomic Beam Spectroscopy, and Muon Spin Rotation (/iSR). The extraction of data from the spectra varies with the methods, the system studied and the physical state of the sample (gas, liquid, unordered or ordered solid). For these procedures the reader is referred to the monographs (D). Further, effective magnetic moments of free radicals are often obtained from static... [Pg.2]

Double-resonance methods, such as ELDOR, can also be used to obtain information on the dynamics of paramagnetic species. Such approaches are not considered in this chapter. Technical aspects and theory of CW ELDOR and ENDOR experiments will not be discussed, as pulsed techniques are nowadays more common, in particular for work on the highly viscous or solid systems that are typical for polymer research. Finally, this chapter is devoted exclusively to the description of the theoretical background and the concepts of double-resonance experiments. Applications are described in Chapter 7. [Pg.27]

The purpose of the present chapter is twofold first, to show that the EMR method is a powerful tool for the study of chemical reaction dynamics of large su-pramolecular entities in the same experimental style that was used by physical organic chemists working with small molecules. This will be outlined in 2. Second, I hope to successfully convince the reader that ENDOR and ESEEM spectra can provide sufficiently accurate and reliable information so that derived parameters... [Pg.85]