Applications of EPR in radiation research
Electron paramagnetic resonance spectroscopy Electron paramagnetic resonance Chemistry Characterization and Evaluation of Materials Effects of Radiation/Radiation Protection Nuclear Chemistry Nucleic Acid Chemistry Theoretical and Computational Chemistry sähkökirjat
Springer
2014
EISBN 9783319092164
From the Contents: PART I Elementary radiation processes.
PART II Solid state radiation chemistry.
PART III Biochemistry, biophysics, and biology applications.
PART IV Material science.
PART V Radiation metrology.
PART VI Geological dating.
EPR dating.
PART VII Advanced EPR techniques.
PART VIII Theoretical tools.
Applications of EPR in Radiation Research is a multi-author contributed volume presented in eight themes: I. Elementary radiation processes (fundamental reaction mechanisms, low temperature radiolysis, quantum solids); II: Solid state radiation chemistry (crystalline, amorphous and heterogeneous systems); III: Biochemistry, biophysics and biology applications (radicals in biomaterials, spin trapping, free-radical-induced DNA damage); IV: Materials science (polymeric and electronic materials, materials for treatment of nuclear waste); V: Radiation metrology (EPR-dosimetry, clinical applications); VI: Geological applications; VII: Advanced techniques (pulsed and optically detected EPR, spatial distributions of radicals, radical ion pairs); VIII: Theoretical tools (density-functional calculations, spectrum simulations).
PART II Solid state radiation chemistry.
PART III Biochemistry, biophysics, and biology applications.
PART IV Material science.
PART V Radiation metrology.
PART VI Geological dating.
EPR dating.
PART VII Advanced EPR techniques.
PART VIII Theoretical tools.
Applications of EPR in Radiation Research is a multi-author contributed volume presented in eight themes: I. Elementary radiation processes (fundamental reaction mechanisms, low temperature radiolysis, quantum solids); II: Solid state radiation chemistry (crystalline, amorphous and heterogeneous systems); III: Biochemistry, biophysics and biology applications (radicals in biomaterials, spin trapping, free-radical-induced DNA damage); IV: Materials science (polymeric and electronic materials, materials for treatment of nuclear waste); V: Radiation metrology (EPR-dosimetry, clinical applications); VI: Geological applications; VII: Advanced techniques (pulsed and optically detected EPR, spatial distributions of radicals, radical ion pairs); VIII: Theoretical tools (density-functional calculations, spectrum simulations).
