Physics at SurfacesPhysics at Surfaces is a unique graduate-level introduction to the physics and chemical physics of solid surfaces, and atoms and molecules that interact with solid surfaces. A subject of keen scientific inquiry since the last century, surface physics emerged as an independent discipline only in the late 1960s as a result of the development of ultra-high vacuum technology and high speed digital computers. With these tools, reliable experimental measurements and theoretical calculations could at last be compared. Progress in the last decade has been truly striking. This volume provides a synthesis of the entire field of surface physics from the perspective of a modern condensed matter physicist with a healthy interest in chemical physics. The exposition intertwines experiment and theory whenever possible, although there is little detailed discussion of technique. This much-needed text will be invaluable to graduate students and researchers in condensed matter physics, physical chemistry and materials science working in, or taking graduate courses in, surface science. |
From inside the book
Results 1-5 of 46
Page 21
... energy of a core electron is a sensitive function of atomic identity. Therefore, measurements of the kinetic energy of electrons ejected from a solid after photon or electron bombardment can provide surfacespecific elemental information ...
... energy of a core electron is a sensitive function of atomic identity. Therefore, measurements of the kinetic energy of electrons ejected from a solid after photon or electron bombardment can provide surfacespecific elemental information ...
Page 22
... energy to the solid (Fig. 2.2). Two types of electrons contribute to this tail. Primary electrons exit the sample ... kinetic energy of the outgoing electron be Ekin = Ets — E2s - B25, (2.2) where E2, and E2 are the binding energies of ...
... energy to the solid (Fig. 2.2). Two types of electrons contribute to this tail. Primary electrons exit the sample ... kinetic energy of the outgoing electron be Ekin = Ets — E2s - B25, (2.2) where E2, and E2 are the binding energies of ...
Page 23
Andrew Zangwill. electron's kinetic energy depends only on the properties of the atom. Similar core-hole decay processes occur for all the atoms of the periodic table (except hydrogen and helium) and the characteristic Auger electron ...
Andrew Zangwill. electron's kinetic energy depends only on the properties of the atom. Similar core-hole decay processes occur for all the atoms of the periodic table (except hydrogen and helium) and the characteristic Auger electron ...
Page 24
... kinetic energy spectrum. The principal disadvantage to AES is that the incident electron beam charges up a non-conducting sample. X-ray photoemission spectroscopy (XPS) is a related surface analysis technique that also takes advantage ...
... kinetic energy spectrum. The principal disadvantage to AES is that the incident electron beam charges up a non-conducting sample. X-ray photoemission spectroscopy (XPS) is a related surface analysis technique that also takes advantage ...
Page 25
... Kinetic energy (eV) 105 “clean' Si 104.4 103 1 0 2 10 i-o-o-o-o-o-o-o-o-o-o: Atomic mass units atoms are knocked (sputtered) off the surface and subjected to. Mass spectroscopy.
... Kinetic energy (eV) 105 “clean' Si 104.4 103 1 0 2 10 i-o-o-o-o-o-o-o-o-o-o: Atomic mass units atoms are knocked (sputtered) off the surface and subjected to. Mass spectroscopy.
Other editions - View all
Common terms and phrases
adatom adsorbate adsorption analysis angle band barrier beam behavior binding energy bulk calculation Chapter charge density chemical chemisorption clean surface constant coverage dangling bond desorption dielectric diffraction dipole dispersion dissociative distribution effect electronic structure electrostatic energy transfer equation equilibrium example excitation exciton experiment experimental Fermi level field frequency gas phase incident interaction ionic jellium kinetic energy lattice layer LDOS LEED magnetization measurements metal surface microscopic mode molecular molecule monolayer occurs orbital oscillator overlayer oxygen particle phase diagram phase transition phonon photoelectron photoemission physisorption plane plasmon polariton polarization potential energy quantum reaction reconstruction resonant level rotational scattering semi-infinite semiconductor solid curve solid surface spectroscopy spectrum spin sticking coefficient substrate surface atoms Surface Science surface tension symmetry temperature theory thermal tight-binding transition metal two-dimensional vacuum valence valence band vibrational wave function wave vector