R.A.F. (Rtd.) D.C.Ae., A.M.I.E.E., A.M.I.E.R.E., A.F.R.Ae.S.
... any field configuration can be the requisite number of plane phase and polarization to suit the ...
... any field configuration can be the requisite number of plane phase and polarization to suit the ...
Lecture 8 - Intro Polymers
... (Root-mean squared end-to-end distance) Often, we want to consider the size of isolated polymer molecules. In a simple approach, “freely-jointed molecules” can be described1 as ...
... (Root-mean squared end-to-end distance) Often, we want to consider the size of isolated polymer molecules. In a simple approach, “freely-jointed molecules” can be described1 as ...
Electromagnetic force density in dissipative isotropic media
... unit tensor, and c is the speed of light in vacuum. The form of equation (28) is not only physically insightful, but also very convenient in view of calculations since for stationary fields the electromagnetic force on an object in a medium can be calculated simply by integrating n · T̂ over the sur ...
... unit tensor, and c is the speed of light in vacuum. The form of equation (28) is not only physically insightful, but also very convenient in view of calculations since for stationary fields the electromagnetic force on an object in a medium can be calculated simply by integrating n · T̂ over the sur ...
![Preparation of [Co(NH3)5Cl]Cl2 Complexes and Characterization of](http://s1.studyres.com/store/data/000967325_1-bcd81ae6a9eb1b96984651f88242862a-300x300.png)
Quantum Hall hierarchy wave functions from Conformal Field Theory
... Reproduces exactly the v = n/(2np+1) CF wave functions. Generates candidate WFs for all (quasielectron condensate) hierarchy states and their qh/qe excitations, ...
... Reproduces exactly the v = n/(2np+1) CF wave functions. Generates candidate WFs for all (quasielectron condensate) hierarchy states and their qh/qe excitations, ...
Lect08
... reduced. The dielectric is sucked into the capacitor. When the charge is constant, the total energy of the capacitor decreases because the presence of the dielectric increases the capacitance . It turns out that the dielectric is pulled in even if the voltage is held constant, e.g., via a battery. O ...
... reduced. The dielectric is sucked into the capacitor. When the charge is constant, the total energy of the capacitor decreases because the presence of the dielectric increases the capacitance . It turns out that the dielectric is pulled in even if the voltage is held constant, e.g., via a battery. O ...
wave - UniMAP Portal
... Whether or not a wave is inverted upon reflection depends on whether the end is free to move or not. ...
... Whether or not a wave is inverted upon reflection depends on whether the end is free to move or not. ...
BGK electron solitary waves: 1D and 3D
... information (Davydov, 1985; Hasegawa and Kodama, 1995) owing to the fact that they retain their shape and velocity during propagation. In the last two decades, solitary potential structures have been observed in many dynamical regions of the Earth’s magnetosphere: the plasma sheet boundary (Matsumot ...
... information (Davydov, 1985; Hasegawa and Kodama, 1995) owing to the fact that they retain their shape and velocity during propagation. In the last two decades, solitary potential structures have been observed in many dynamical regions of the Earth’s magnetosphere: the plasma sheet boundary (Matsumot ...
Dispersion relations for electromagnetic waves in a dense
... of the electrons due to the electron-1/2 spin effect. The QED (vacuum polarization) effects, which contribute to the nonlinear electron current density, modify the refractive index. Our results concern the propagation characteristics of perpendicularly propagating high-frequency electromagnetic wave ...
... of the electrons due to the electron-1/2 spin effect. The QED (vacuum polarization) effects, which contribute to the nonlinear electron current density, modify the refractive index. Our results concern the propagation characteristics of perpendicularly propagating high-frequency electromagnetic wave ...
Density of states
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In solid-state and condensed matter physics, the density of states (DOS) of a system describes the number of states per interval of energy at each energy level that are available to be occupied. Unlike isolated systems, like atoms or molecules in gas phase, the density distributions are not discrete like a spectral density but continuous. A high DOS at a specific energy level means that there are many states available for occupation. A DOS of zero means that no states can be occupied at that energy level. In general a DOS is an average over the space and time domains occupied by the system. Localvariations, most often due to distortions of the original system, are often called local density of states (LDOS). If the DOS of an undisturbedsystem is zero, the LDOS can locally be non-zero due to the presence of a local potential.