T. J. DeLyon scite author profile

Special Issue Paper 657 FERMI LEVEL ENHANCED INTERDIFFUSIONThe fabrication of all HgCdTe-based infrared detectors involves the formation of one or more heterointerfaces. With the increasing interest in developing detectors in the SWIR as well as the MWIR and LWIR bands, and the desire for multispectral sensitivity, the number and complexity of hetero-interfaces is increasing. Because the performance of these detectors depends critically on the precise placement of the hetero-interfaces, any interdiffusion at these interfaces must be understood and controlled. Although much work has been done in this area, the mechaExcessive dopant or compositional mixing (interdiffusion) during the processing of HgCdTe photodiodes can lead to significant reductions in device performance. With the advent of multi-color and wider bandgap detectors, processes developed for single color LWIR and MWIR devices may not be transferable to the more complex structures. An important factor to account for in processing multicolor and wider gap HgCdTe is the effect of the Fermi level on point defect (PD) concentrations. In general, the density of PDs that have donor states in the band gap will be boosted in the presence of acceptors through the energy gained by the donor state electrons dropping into the vacant acceptor states. The density of PDs that have acceptor states in the band gap will be boosted in the presence of donors through a similar compensation mechanism. This Fermi-level effect is increasingly more important as the band gap is widened. Since almost all diffusion is mediated by either native and/or dopant point defects, and the intrinsic carrier concentration is relatively low at typical processing temperatures, significant broadening of composition and dopant profiles can occur in moderately and heavily doped HgCdTe. In this paper, we illustrate the Fermilevel effect on diffusion with two examples: compositional interdiffusion in multicolor detectors and diffusion of indium in MWIR and SWIR detectors.

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Molecular beam epitaxy of HgCdTe

Wu¹,

DeLyon²,

Rajavel³

et al. 1997

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Halmos

Jack

Asbrock

et al. 2001

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T. J. DeLyon

Shear deformation and strain relaxation in HgCdTe on (211) CdZnTe

HgCdZnTe quaternary materials for lattice-matched two-color detectors

Enhanced diffusion and interdiffusion in HgCdTe from fermi-level effects

Molecular beam epitaxy of HgCdTe

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