Thermalization of Positrons in Metals

Lee-Whiting, G.E.

doi:10.1103/physrev.97.1557

Cited by 91 publications

(16 citation statements)

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“…1 " 4 The results of these experiments have been shown to be compatible with the formation of a cavity in helium by an excess electron due to the repulsive exchange force between the excess electron and helium atoms. 5 " 8 An equilibrium cavity size is obtained by balancing the zero-point kinetic pressure of the electron by the surface and hydrostatic pressures on the cavity.…”

mentioning

confidence: 78%

“…In fact, our final approximate formula is identical with that written some time ago by Lee-Whiting. 4 An essential difference, however, is that in the present result the Fermi-Thomas parameter, A, replaces the semiphenomenological screening length used by Lee-Whiting. When this change is made the resulting thermalization time increases considerably because of the strong (A 4 ) dependence on screening length.…”

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confidence: 83%

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Minimum Energy of Positrons in Metals

1967

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This Letter reports an important new discovery in positron annihilation in metals, viz., that positrons are not always thermalized before annihilation and thus that the ultimate resolution of the technique is limited. The next paragraphs outline the experimental and theoretical discoveries of this phenomenon, and present the results of calculation and measurements.Observations of positron motions in metals, first reported last year, 1 ' 2 have been continued in a series of metals over a wider range of temperatures. The positron-annihilation technique measures the momentum distribution of all annihilating pairs of electrons and positrons, i.e., the convolution of the distribution of electron momentum with positron momentum. By examining the momentum distribution of annihilation photons in the region corresponding to the Fermi momentum, where the electron distribution has a sharp cutoff, information can be obtained concerning positron motion. In terms of experimental measurements, the angular correlation of annihilation photons yields the usual parabolic distributions shown in Fig. 1. It can be seen that as the temperature of the specimen is raised the smearing of the parabolic cutoff is increased. This effect was naturally taken to imply increased motion of the positron in the hotter metal. Only one parameter of the positron motion can be obtained from present experimental results. We have called this parameter the positron effective temperature, having assumed for its energy distribution the Boltzmann formula for free particles.Data have been collected for positrons annihilating in Li, Na, K, Rb, and Ca at various temperatures, and analyzed by a method similar to that described in Ref. 2. In brief, the analysis consisted of comparing the data in the "slope" presentation (i.e., the deriva-

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confidence: 78%

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confidence: 83%

Minimum Energy of Positrons in Metals

1967

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“…The fundamental result of this phenomenon is the positron thermalization time, during which the positron dissipates its initial energy. Its calculated value is 3 10 -12 s. [1].…”

Section: Experimental and Software-supported Investigationsmentioning

confidence: 93%

Physicochemical and Radiation Modification of Titanium Alloys Structure

Mukashev¹,

Umarov²

2013

Titanium Alloys - Advances in Properties Control

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“…physica status solidi(b) 68 Positron angular correlation arrangement;(1) ,sample, (2) source, (3) parabolic lead shield, (4) supplementary slits, (5) rf coil, (6) movable detector,(7) fixed detector, (8) angular correlation without r f field,(9) angular correlation with rf field both singles, were added pointwise for all the runs separately for the rf field on and off conditions. These curves are shown inFig.…”

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confidence: 99%