The bulk generation-recombination processes and the carrier lifetime in mid-wave infrared and long-wave infrared liquid nitrogen cooled HgCdTe alloys

Jóźwikowski, K.; Kopytko, M.; Rogalski, Antoni

doi:10.1063/1.4745872

Cited by 29 publications

(9 citation statements)

References 59 publications

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“…The dark current calculations include thermal generation mechanisms, Auger 1, Auger 7, and SRH through metal-site vacancies and dislocation related centers. 25 The metal-site vacancy concentration was assumed to be N T = 1 9 10 13 cm À3 with an ionization energy 0.75E g above the valence band edge, and carrier capture cross-sections of r n = r p = 5 9 10 À16 cm 2 . The bulk dislocations density was assumed to be G DIS = 1 9 10 5 cm À2 , with the mean energy of the dislocation band at 0.32E g above the valence band edge, and carrier cross sections equal to r n = r p = 5 9 10 À15 cm 2 .…”

Section: Barrier Designmentioning

confidence: 99%

Engineering the Bandgap of Unipolar HgCdTe-Based nBn Infrared Photodetectors

Kopytko

Wróbel

Jóźwikowski

et al. 2014

Journal of Elec Materi

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Design of practically realizable unipolar HgCdTe nBn photodetectors has been studied in detail by numerical analysis. The simulations reported herein reveal that, by optimization of barrier doping, dark current levels can be reduced and collection efficiency substantially improved. It is shown that p-type doping of the barrier layer can significantly reduce the effective potential barrier arising from the valence band offset between the absorber and barrier regions, thus enabling HgCdTe nBn detector operation under near zero-bias conditions. However, relatively high electric fields in the space charge regions near the barrier/absorber interface result in enhanced trapassisted Shockley-Read-Hall thermal generation. Our calculations indicate that nBn HgCdTe detectors with barriers engineered by use of HgTe/ Hg 0.05 Cd 0.95 Te superlattices have, potentially, substantially better valence band alignment without the need for p-type doping.

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Section: Barrier Designmentioning

confidence: 99%

Engineering the Bandgap of Unipolar HgCdTe-Based nBn Infrared Photodetectors

Kopytko

Wróbel

Jóźwikowski

et al. 2014

Journal of Elec Materi

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“…Carrier recombination in Hg 1− x Cd x Te‐based structures was intensively studied, but mainly in bulk epilayers in regard to their use for IR detectors. There are fewer studies of recombination in narrow gap QWs, especially under intense optical excitation, which is typical for lasers.…”

Section: Introductionmentioning

confidence: 99%

Carrier Recombination, Long‐Wavelength Photoluminescence, and Stimulated Emission in HgCdTe Quantum Well Heterostructures

Rumyantsev

Fadeev

Aleshkin

et al. 2019

Physica Status Solidi (b)

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Interband photoluminescence (PL) and stimulation emission (SE) from HgTe/ HgCdTe quantum well (QW) heterostructures are studied in 5-20 mm wavelength range in regard to long-wavelength lasing applications. The authors obtain carrier lifetimes using time-resolved photoconductivity measurements and show that the dominating mechanism of carrier recombination changes from the radiative process to the non-radiative one as the bandgap is decreased, limiting the "operating" temperature for SE. The authors suggest that decreasing the QW width should reverse the balance in carrier recombination in favor of radiative processes and demonstrate 75 K improvement in the "operating" temperature in structure with narrower QW.of the band structure of narrow-gap HgTe/ HgCdTe heterostructures on carrier recombination mechanisms. [4] Recently, it was shown that HgCdTe-based QW can provide stimulated emission in the very longwavelength IR, [5] suggesting that such structures can be interesting for longwavelength emitters.At present moment, the best-performing semiconductor sources for far IR range are quantum cascade lasers (QCLs). They demonstrate ultimate figures of merit almost in the entire IR range. [6] The only "blind spot" of QCLs caused by the strong lattice absorption in traditional production materials (GaAs and InP) lies at wavelengths between 20 and 60 μm. InAs-based and Al-free QCLs are tackling this wavelength range from the mid-IR side, [7] while GaN QCLs have been proposed for frequencies above 5 THz. [8] However, interband lasers are also of interest since they are less demanding from the technological viewpoint and allow wavelength tuning with temperature. The cornerstone of effective light emitter, especially in far infrared range (FIR) range, is to suppress the non-radiative recombination, in

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“…carrier lifetimes increase with the bandgap indicates that recombination is non-radiative. Review of literature data suggests that the dominating mechanism of carrier recombination is Shockley-Read-Hall (SRH) process [9][10][11]. However, according to recent calculation of carrier recombination rates [11] lifetime of 9.2 µs measured in our bulk epilayer (x = 0.22) practically coincides with the calculated radiative lifetime for n-doped (5×10 14 cm -3…”

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confidence: 66%

“…One can see that PC decay time grows with x up to ~ 10 µs at x = 0.22 and then slightly decreases. The radiative lifetime is known to decrease with the bandgap [9]; hence, such behavior, i.e. carrier lifetimes increase with the bandgap indicates that recombination is non-radiative.…”

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confidence: 99%

“…Firstly, calculations of recombination rates that exploit the full band structure obtained in hybrid pseudopotential tight-binding Hamiltonian model predict longer Auger time than those calculated with widely used analytical expressions [11]. Secondly, at high carrier densities Auger recombination rates are affected by Coulomb screening that should also increase the Auger recombination time [9]. Though at rather high temperature as 100K the Auger recombination lifetime is of the same order of magnitude as spontaneous radiative recombination time according to [11] somewhat of Auger mitigation is indirectly confirmed by our experiments as well.…”

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confidence: 99%

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Investigation of possibility of VLWIR lasing in HgCdTe based heterostructures

Morozov

Rumyantsev

Kadykov

et al. 2015

J. Phys.: Conf. Ser.

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HgCdTe material has been intensively studied for more than half a century due to its paramount importance for infrared optoelectronics. Development of IR sensors has driven the HgCdTe growth techniques, in particular molecular beam epitaxy (MBE), which nowadays allows producing high quality epitaxial structures with in situ control of layers composition and thickness. Besides bulk epilayers with high uniformity and low residual carrier density (~10 14 cm -3) MBE can also provide HgCdTe based heterostructures with quantum wells (QW) energy spectrum of which can be tuned by changing QW width and Cd content in it. A number of peculiar fundamental properties [1,2] were demonstrated in such systems as well as pronounced long-wavelength photoconductivity (PC) up to THz range [3,4]. However, processes of light emission from narrow gap HgCdTe were less investigated; in particular, spectra of interband photoluminescence (PL) from HgCdTe based structures in very long wavelength infrared range (VLWIR) are scarce in literature. Stimulated emission was investigated only in wavelength region up to 5.3 µm [5,6]. In this work we have examined the optical properties of a number of Hg1-xCdxTe bulk epilayers and heterostructures with QW based on narrow gap HgCdTe aiming to reveal the prospects of such structures for laser development in LWIR and VLWIR ranges.

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The bulk generation-recombination processes and the carrier lifetime in mid-wave infrared and long-wave infrared liquid nitrogen cooled HgCdTe alloys

Cited by 29 publications

References 59 publications

Engineering the Bandgap of Unipolar HgCdTe-Based nBn Infrared Photodetectors

Engineering the Bandgap of Unipolar HgCdTe-Based nBn Infrared Photodetectors

Carrier Recombination, Long‐Wavelength Photoluminescence, and Stimulated Emission in HgCdTe Quantum Well Heterostructures

Investigation of possibility of VLWIR lasing in HgCdTe based heterostructures

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