Conservation of Lateral Momentum in Heterostructure Integrated Thermionic Coolers

Vashaee, Daryoosh; Shakouri, Ali

doi:10.1557/proc-691-g6.5

Cited by 12 publications

(9 citation statements)

References 22 publications

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“…This structure is intentionally chosen to compare the model presented here with previous results on thermionic cooling performance. [30][31][32] It has been shown that the figure-of-merit for thermionic cooling is about half of that of thermoelectric cooling in InGaAs. In Fig.…”

Section: Ingaas Based Superlatticesmentioning

confidence: 99%

Electronic and thermoelectric transport in semiconductor and metallic superlattices

Vashaee

Shakouri

2004

Journal of Applied Physics

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142

124

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A detailed theory of nonisothermal electron transport perpendicular to multilayer superlattice structures is presented. The current-voltage (I-V) characteristics and the cooling power density are calculated using Fermi-Dirac statistics, density-of-states for a finite quantum well and the quantum mechanical reflection coefficient. The resulting equations are valid in a wide range of temperatures and electric fields. It is shown that conservation of lateral momentum plays an important role in the device characteristics. If the lateral momentum of the hot electrons is conserved in the thermionic emission process, only carriers with sufficiently large kinetic energy perpendicular to the barrier can pass over it and cool the emitter junction. However, if there is no conservation of lateral momentum, the number of electrons participating in a thermionic emission will increase. This has a significant effect on the I-V measurements as well as the cooling characteristics. Theoretical calculations are compared with the experimental dark current characteristics of quantum well infrared photodetectors and good agreement over a wide temperature range for a variety of superlattice structures is obtained. In contrast with earlier studies, it is shown that lateral momentum is conserved for the case of electron transport in planar semiconductor barriers.

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Section: Ingaas Based Superlatticesmentioning

confidence: 99%

Electronic and thermoelectric transport in semiconductor and metallic superlattices

Vashaee

Shakouri

2004

Journal of Applied Physics

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142

124

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“…Two cases of electron transports in the superlattice are considered: when transverse momentum during thermionic emission is conserved and when transverse momentum is not conserved. [10][11][12][13] The plot shows that, in both cases, superlattice transport does not improve much the ZT over the bulk values. 14 Basically, this is due to the small conduction band offset of the SiGe/ Si superlattice, which is about 12% ͑E b ϳ 23 meV for the proposed structure͒.…”

Section: N-type Sige/si Superlattice Power Generatormentioning

confidence: 95%

Thermionic power generation at high temperatures using SiGe∕Si superlattices

Vashaee¹,

Shakouri²

2007

Journal of Applied Physics

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Recent studies have predicted that heterostructure superlattices can enhance the effective thermoelectric power factor significantly through selective emission of hot carriers via thermionic emission. Here, we study the potential of SiGe∕Si superlattices for power generation at high temperatures. A detailed theory based on Boltzmann transport equation is developed which takes into account multiple valleys. We show that thermionic emission provides only a modest improvement in the power factor. This is due to the fact that SiGe is a multivalley semiconductor and it has a large density of states. With reasonable dopings, Fermi energy in SiGe alloy is very close to the band minimum so that the symmetry of the differential conductivity does not change very much with small barrier superlattices. Particularly at high temperatures when the thermal spread of the carriers is much larger than the Fermi energy in the band, superlattice energy filtering is not effective.

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“…One can describe the effect of potential barriers as a mean to increase the thermoelectric power factor (the square of the Seebeck coefficient times the electrical conductivity). The fact that there is a trade-off between electrical conductivity and the Seebeck coefficient and that we can not keep increasing the number of free carriers and get higher and higher power factors is an intriguing effect which has not been discussed in detail from a fundamental point of view 18,19,20 . One way to look at this problem, is to consider the differential conductivity of electrons in typical semiconductors and metals.…”

Section: Single and Multibarrier Thermionic Devicesmentioning

confidence: 99%

“…volume V 1 in Fig. 2(b)) 16,17,19,31,32 . There are many hot electrons that have large transverse momentum.…”

Section: Conservation Of Tramsverse Momentum In Thermionic Emissionmentioning

confidence: 99%

Thermoelectric, thermionic and thermophotovoltaic energy conversion

Shakouri

2005

ICT 2005. 24th International Conference on Thermoelectrics, 2005.

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Key characteristics of thermoelectric, ballistic thermionic and quasi diffusive thermionic energy converters are compared. First, the main assumptions used to derive the linear Boltzmann transport equations for electrons are examined and the possibility that a higher order transport coefficient may become relevant is discussed. In the linear transport regime, there is a fundamental trade off between high Seebeck coefficient and high electrical conductivity for bulk materials and for many multilayer structures due to the interplay between electronic density-of-states (DOS) and electron group velocity and also due to the shape of DOS versus energy curve deep inside a band. While low dimensional structures alter the density-of-states, a similar trade off still exists. If large barrier heights and high doping concentrations could be achieved solid-state thermionic energy converters would be able to alleviate this trade off, thereby achieving a very high thermoelectric power factor. For this to occur, the electron transverse momentum perpendicular to heterostructure barriers must not be conserved. This can be achieved with non-planar structures or with embedded nanostructures. Finally, a comparison between thermoelectric/ thermionic devices and thermophotovoltaic energy converters shows a difference in the average energy of the emitted hot carriers due to the difference between electronic and photonic density-of-states in the reservoirs. The use of both electrons and photons from a hot reservoir or the engineering of the reservoir density-ofstates may provide additional means to achieve higher efficiency in energy conversion devices and to approach the limit given by the entropy generation more easily.

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Conservation of Lateral Momentum in Heterostructure Integrated Thermionic Coolers

Cited by 12 publications

References 22 publications

Electronic and thermoelectric transport in semiconductor and metallic superlattices

Electronic and thermoelectric transport in semiconductor and metallic superlattices

Thermionic power generation at high temperatures using SiGe∕Si superlattices

Thermoelectric, thermionic and thermophotovoltaic energy conversion

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