Both textbook and monograph, "Spectroscopy in Catalysis" describes the most important modem analytical techniques used to investigate catalysts or related systems, such as thin films and single crystals that are used to model catalytic surfaces. These techniques include electron spectroscopic (XPS, UPS, AES, EELS), ion spectroscopics (SIMS, SNMS, RBS, LEIS), vibrational spectroscopies (infrared and Raman spectroscopy, EELS), mass spectroscopic and temperature programmed techniques (TPR, TPO, TDS), diffraction (XRD, LEED, EXAFS), and microscopy (TEM, SEM, STEM, STM, AFM, FEM and FIK. Like a monograph, it covers recent research. Like a textbook, it offers numerous graphics to explain the basics of each spectroscopic technique. Each chapter provides current applications to illustrate the type of information that the technique provides and evaluates the possibilities and limitations of the technique.
Sprache
Verlagsort
Zielgruppe
Für höhere Schule und Studium
Für Beruf und Forschung
Illustrationen
Maße
Höhe: 245 mm
Breite: 174 mm
Gewicht
ISBN-13
978-3-527-28593-8 (9783527285938)
Schweitzer Klassifikation
Part 1: Temperature programmed techniques: temperature programmed reduction oxidation; sulfidation; desorption and reaction spectroscopy. Part 2 Photoemission and auger spectroscopy: XPS; UPS; AES. Part 3 The ion spectroscopies: secodary ion and neutral mass spectroscopy; Rutherford backscattering and low energy ion spectroscopy; Part 4 Moessbauer spectroscopy. Part 5 Diffreaction and EXAFS: X-ray diffraction; low energy electron diffraction; extended X-ray absorption fine structure. Part 6 Microscopy and related techniques: transmission and scanning electron microscopy; scanning tunneling and atomic force microscopy; field emission; field ion microscopy. Part 7 The vibrational spectroscopies: infrared; Raman; electron energy loss spectroscopy. Part 8 Case studies in catalysis characterization: structure of supported whodium catalysts; the active phase in sulfided hydrotreating catalysts; alkali promoter effects on noble metal surfaces. Appendices: theory of metal surfaces; chemosorption theory; magnetism in small particles.
