Thermal Conductivity of Electron-Irradiated Germanium

Vook, F. L.

doi:10.1103/physrev.138.a1234

Cited by 26 publications
(12 citation statements)

~~References 29 publications~~

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“…14 For a given generation rate the electric field of the calculated generation rate seems to be roughly 15% below the experimental field although the slopes of the curves are in excellent agreement. The difference in the fields could be accounted for by saying that the effective electron velocity is not v but really v cos0, since this would require a slight increase in the field to obtain the same theoretical generation rate.…”

mentioning
confidence: 63%

Bombardment-Produced Defects inp-Type Germanium at Low Temperatures
Flanagan¹,
Klontz²
1968
Phys. Rev.
30
3
9
0
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Lattice defects produced in nondegenerate (1-10 Q, cm) />-type germanium at 10°K by 1.0-MeV electrons cannot be detected electrically immediately following bombardment. Illumination by light having energy less than the band gap reveals the defects in the form of ionized donors. During ionization, the carrier concentration decreases as the sum of two exponentials, with time constants in the ratio «*6 to 1. Subsequent thermal-annealing investigations show two recovery stages in the temperature range 40 to 70°K. These stages appear to be intimately related to the time constants for decay during illumination, with the lowtemperature recovery associated with the fast component and the high-temperature recovery with the slow component. Both stages of recovery are independent of the type of impurity. Regardless of the extent of illumination, the electrical conductivity and the carrier concentration have essentially the same values they had prior to bombardment. When illuminated sufficiently long to ionize all the defects, the ionized donors become extremely susceptible to annihilation when the temperature is increased, and the situation after heating to 70 °K represents true annealing. Illumination for shorter times results in some un-ionized defects which do not anneal upon heating to 70°K. Isochronal heating to 150°K then causes a transformation of most of the unannealed defects into a configuration which the authors call a "two-state defect," the same defect observed following irradiation at 77°K. The transformed defects break up at about 200°K. Along with the higher-temperature effects, some impurity-dependent recovery stages are noted. A model to partially account for the results is briefly discussed. 790 T. M. FLANAGAN AND E. E. KLONTZ

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mentioning
confidence: 63%

Bombardment-Produced Defects inp-Type Germanium at Low Temperatures
Flanagan¹,
Klontz²
1968
Phys. Rev.
30
3
9
0
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~~show abstract~~

“…IIIC we analyze the special case of the intraconfiguration transition 5 D 0 -^7FQ of Sm 2+ for which the even coupling vanishes, and show that for it the vibronic structure approximates a part of the density of states of the vibrations of the undisturbed lattice. Within the Born-Oppenheimer approximation, 9 we write the total wave function for the coupled electronlattice system as *(',e) = *(r,G)*(0), (la) where \[/, the electronic wave function, is a function of the electron coordinates (r) and nuclear normal mode (Q) coordinates, and <j> is the nuclear wave function. Further, under the Franck-Condon principle, that the positions of the nucleii remain fixed during an electronic transition, we may write the probability of a dipole transition between electron-lattice states as 1 (%>n'\P<\*Jn)=(f j \P*\4'i)…”

Section: Discussionmentioning
confidence: 99%

“…For the case of inversion symmetry (case II), the electric-dipole transition probability becomes, to terms of first order in U K Q K , (9) where the subscripts u and g refer to odd and even vibrational modes. The displacement a K in (9) is finite only for the even modes, since for case II the charge distribution |#/Vy| is on a time average still even, and can interact only with the even vibrations to give a displacement of the even normal coordinates, Q Kg .…”

Section: Ei-eymentioning
confidence: 99%

“…It is not clear at this time how this complication affects the perturbation treatment used to obtain Eq. (9) or how it affects the assumption, inherent in the electrostatic-coupling small. The vibronic structure recently reported by Kiss 26 for the transitions 77Y 2 > -> 8£< 2 > and 1T^ -* 8T 2 (2) of Dy 2+ in CaF 2 and SrF 2 may be an indication, however, that a K need not always be small.…”

Section: Case II Inversion Symmetrymentioning
confidence: 99%

See 1 more Smart Citation
Bound-Electron-Lattice Coupling and Vibronic Spectra
Bron¹
1965
Phys. Rev.
43
0
17
0
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The radial extent of the coupling between the bound electronic states of a defect ion in a crystal and the vibrations of the lattice ions is investigated. An electrostatic-coupling model is used to evaluate the electronlattice interaction. It is found that those electronic transitions which involve a change in configuration are coupled primarily to the vibrations of ions in the immediate vicinity of the defect. Consequently, if there exist local or pseudolocalized vibrations, the resultant vibronic spectra are dominated by transitions to vibrational modes which have high local amplitude. In contrast, it is found that in general, electronic transitions within a configuration are coupled to nonlocalized vibrations as well as to the localized vibrations. In the special case of the transition 5 JD 0 -> 7 FQ of Sm 2+ , the coupling is primarily to nonlocalized vibrations, so that the vibrations resemble those of ions of the undisturbed lattice. The observed vibronic structure accompanying this transition of Sm 2+ in the alkali halides is presented. A comparison is made for Sm 2+ :KBr between the singularities in the phonon density of states as observed in the vibronic structure, and those predicted from the published dispersion curves of KBr obtained from neutron-scattering data. The agreement is found to be very good. The vibronic structure accompanying the same transition of Sm 2+ in the alkaline-earth halides is also discussed. 1 W. E. Bron and M. Wagner, Phys. Rev. 139, A233 (1965).
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“…This observation was compared to the phenomenon already noticed by Goff and Pearlman 11 and related, on the basis of the Keyes model, 8 to the scattering of phonons by electrons bound to donors. The effects of electron 12 and fast-neutron 10 ' 13 irradiations on the thermal conductivity of initially ^-type germanium were also studied: A pronounced decrease of K on the lowtemperature side of the peak was obtained. In both studies, however, the electron and fast-neutron doses used were such that the crystals measured after irradiations were all converted to ^>-type.…”

Section: B I Introductionmentioning
confidence: 98%

Effects of Electron Irradiation on the Thermal Conductivity ofn- andp-Type Germanium
Albany¹,
Vandevyver²
1967
Phys. Rev.
7
0
1
0
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The change in the low-temperature thermal conductivity K of antimony-doped germanium was investigated in the ^-to-^-type conversion region induced by 4-MeV electron irradiation (1.3X10 17 to 1.6X10 18 electrons/cm 2 ) performed at about 40°C. The thermal conductivity was found to decrease in the neighborhood of the peak and just below it, after the first electron dose (1.3X10 17 electrons/cm 2 ). With higher electron fluxes, K increased over the whole temperature range 5-80 °K, reaching values higher than that of unirradiated germanium. The initial decrease of K is at present not well understood, but is likely to be related to scattering of phonons by bombardment-introduced levels. The further increase of K appears to be characteristic of the depletion of donor electrons by radiation-induced acceptor defects. This explanation is consistent with the Keyes model relative to scattering of phonons by occupied donors. No noticeable change in K was obtained in ^-type germanium for electron doses up to 1.7 X10 18 electrons/cm 2 . This behavior indicates that either the radiation-induced levels involve no particular modification of the initial scattering mechanisms, or most likely the defect introduction rate is much lower than in w-type, the small amount of defects produced being of negligible effect on K. B I. INTRODUCTIONETWEEN the different mechanisms of phonon scatterings which take place in the low-temperature range 1 " 5 (boundary effect; mass-difference, strain-field, and dislocation scatterings; phonon-phonon collisions), it is shown that electron-phonon interaction 6 " 9 can be an important scattering source, allowing to account for certain thermal conductivity results, which are unexplainable on the basis of only the above mentioned scatterings.In a previous paper, 10 we have pointed out that the thermal conductivity K of antimony-doped germanium below the peak was lower than the thermal conductivity limited by boundary effect and isotope scattering. This observation was compared to the phenomenon already noticed by Goff and Pearlman 11 and related, on the basis of the Keyes model, 8 to the scattering of phonons by electrons bound to donors. The effects of electron 12 and fast-neutron 10 ' 13 irradiations on the thermal conductivity of initially ^-type germanium were also studied: A pronounced decrease of K on the lowtemperature side of the peak was obtained. In both studies, however, the electron and fast-neutron doses used were such that the crystals measured after irradia-

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Thermal Conductivity of Electron-Irradiated Germanium

Cited by 26 publications

References 29 publications

Bombardment-Produced Defects inp-Type Germanium at Low Temperatures

Bombardment-Produced Defects inp-Type Germanium at Low Temperatures

Bound-Electron-Lattice Coupling and Vibronic Spectra

Effects of Electron Irradiation on the Thermal Conductivity ofn- andp-Type Germanium

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