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Radius constant energy

Covalent Radius Constant Energy Radius Covalent Radius Constant Energy Radius... [Pg.144]

In XPS the photoelectrons are retarded to a constant energy, called the pass energy, as they approach the entrance slit. If this were not done, Eq. (2.5) shows that to achieve an absolute resolution of 1 eV at the maximum kinetic energy of approximately 1500 eV (using A1 Ka radiation), and with a slit width of 2 mm, would require an analyzer with an average radius of about 300 cm, which is impracticable. Pass energies are selected in the range 20-100 eV for XPS, which enables the analyzer to be built with a radius of 10-15 cm. [Pg.14]

Relative Potential Bubble Energy (RPBE) The cube of the ratio of the maximum bubble radius constants (J s) ... [Pg.62]

The constant, which is a property of the particular liquid-solid system, can be calculated from the molecular properties of the two substances dipole moment, polarizability, ionization energy, and molecular radius. Free energies have been calculated from contact angle data for the following solids polytetrafluoroethylene, polyhexafluoropro-p y 1 e n e, poly(trifluoromonochloro)ethylene, and a monolayer of perfluorolauric acid. [Pg.74]

A complex exothermic chemical reaction occnrs in a plng-flow tubnlar reactor with constant energy flux across the wall at radius R. All thermophysical properties of the reactive fluid are independent of temperature and conversion. Derive the relations between conversion flnid temperatnre T, and reactor volume VppR at high-mass and high-heat-transfer Peclet nnmbers. [Pg.104]

Figure 4.3 The available phase space of a constant energy classical system with two degrees of freedom, p and p2, is the perimeter of a circle of radius p =... Figure 4.3 The available phase space of a constant energy classical system with two degrees of freedom, p and p2, is the perimeter of a circle of radius p =...
Within the framework of the same dielectric continuum model for the solvent, the Gibbs free energy of solvation of an ion of radius and charge may be estimated by calculating the electrostatic work done when hypothetically charging a sphere at constant radius from q = 0 q = This yields the Bom equation [13]... [Pg.836]

In the reaction field method, a sphere is constructed around the molecule with a radius equal to the cutoff distance. The interaction with molecules that are within the sphere is calculated explicitly. To this is added the energy of interaction with the medium beyond the sphere, which is rnodelled as a homogeneous medium of dielectric constant g (Figure 6.23). The electrostatic field due to the surrounding dielectric is given by ... [Pg.353]

Some physical constants for selenium are given in Table 1. More extensive data and many sources are available (1 5). For a selenium atom, the covalent radius is ca 0.115 nm, the electron affinity for two electrons is ca —2.33 eV, ie, energy absorbed, and the first ionization potential is 9.75 eV. [Pg.326]

Consider an alchemical transformation of a particle in water, where the particle s charge is changed from 0 to i) (e.g., neon sodium q = ). Let the transformation be performed first with the particle in a spherical water droplet of radius R (formed of explicit water molecules), and let the droplet then be transferred into bulk continuum water. From dielectric continuum theory, the transfer free energy is just the Born free energy to transfer a spherical ion of charge q and radius R into a continuum with the dielectric constant e of water ... [Pg.188]

The premise of the above analysis is the fact that it has treated the interfacial and bulk viscoelasticity equally (linearly viscoelastic experiencing similar time scales of relaxation). Falsafi et al. make an assumption that the adhesion energy G is constant in the course of loading experiments and its value corresponds to the thermodynamic work of adhesion W. By incorporating the time-dependent part of K t) into the left-hand side (LHS) of Eq. 61 and convoluting it with the evolution of the cube of the contact radius in the entire course of the contact, one can generate a set of [LHS(t), P(0J data. By applying the same procedure described for the elastic case, now the set of [LHS(t), / (Ol points can be fitted to the Eq. 61 for the best values of A"(I) and W. [Pg.127]

The simplest reaction field model is a spherical cavity, where only the net charge and dipole moment of the molecule are taken into account, and cavity/dispersion effects are neglected. For a net charge in a cavity of radius a, the difference in energy between vacuum and a medium with a dielectric constant of e is given by the Bom model. ... [Pg.395]

See other pages where Radius constant energy is mentioned: [Pg.85]    [Pg.315]    [Pg.165]    [Pg.145]    [Pg.146]    [Pg.68]    [Pg.191]    [Pg.192]    [Pg.97]    [Pg.298]    [Pg.286]    [Pg.112]    [Pg.806]    [Pg.835]    [Pg.2976]    [Pg.3026]    [Pg.49]    [Pg.610]    [Pg.611]    [Pg.84]    [Pg.240]    [Pg.114]    [Pg.541]    [Pg.255]    [Pg.520]    [Pg.381]    [Pg.196]    [Pg.94]    [Pg.32]    [Pg.95]    [Pg.324]    [Pg.1192]    [Pg.655]    [Pg.29]    [Pg.223]   
See also in sourсe #XX -- [ Pg.145 ]



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