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Page 130
... density of 40 1.0218 air as a function of 60 1.0333 pressure is given in 80 1.0439 AIP Handbook , p . 100 1.0548 4-83 . Pentane ( C , H12 ) at 303 ° K Pressure ( atm ) Density ( gm / cm3 ) € 1 0.613 1.82 103 0.701 1.96 4 × 103 0.796 ...
... density of 40 1.0218 air as a function of 60 1.0333 pressure is given in 80 1.0439 AIP Handbook , p . 100 1.0548 4-83 . Pentane ( C , H12 ) at 303 ° K Pressure ( atm ) Density ( gm / cm3 ) € 1 0.613 1.82 103 0.701 1.96 4 × 103 0.796 ...
Page 133
... density J , measured in units of positive charge crossing unit area per unit time , the direction of motion of the charges defining the direction of J. In electrostatic units , current density is measured in statcoulombs per square ...
... density J , measured in units of positive charge crossing unit area per unit time , the direction of motion of the charges defining the direction of J. In electrostatic units , current density is measured in statcoulombs per square ...
Page 448
... density of electrons is the same in each . Since there are numerous calculated curves of energy loss based on Bethe's formula ( 13.44 ) , it is often convenient to tabulate the decrease in energy loss due to the density effect . This is ...
... density of electrons is the same in each . Since there are numerous calculated curves of energy loss based on Bethe's formula ( 13.44 ) , it is often convenient to tabulate the decrease in energy loss due to the density effect . This is ...
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Common terms and phrases
4-vector Ampère's law angle angular distribution approximation atomic axis boundary conditions calculate Chapter charge density charge q charged particle coefficients collisions component conductor consider coordinates cross section current density cylinder d³x delta function dielectric constant diffraction dimensions dipole direction discussed E₁ electric field electromagnetic fields electron electrostatic energy loss expansion expression factor frequency given Green's function impact parameter incident particle inside integral inversion Laplace's equation linear Lorentz transformation macroscopic magnetic field magnetic induction magnetic moment magnitude Maxwell's equations meson modes molecules momentum motion multipole nonrelativistic normal obtain oscillations P₁ parallel plasma point charge Poisson's equation polarization problem radiation radius region relativistic result scalar scalar potential scattering shown in Fig shows solution spherical surface surface-charge density theorem transverse unit V₁ vanishes vector potential velocity volume wave equation wave number wavelength written zero ΦΩ