Report on Army Research Office Grant W911NF-10-1-0442 (Massachusetts Institute of Technology)

Abstract

In collaboration with ARDEC Benet Labs, Rensselaer Polytechnic Institute (RPI), and Harvard University, we conducted a systematic investigation of sub-band gap optical response in hyper-doped silicon. Doping silicon with non-equilibrium concentrations of chalcogen atoms (i.e., hyperdoping) yields remarkably strong optical absorptance to wavelengths as long as 5 microns, and measureable photodiode response at wavelengths as long as 1.5 microns. Despite these remarkable properties, photodiode response remains weak at sub-band gap wavelengths shorter than 1.5 microns, and negligible at longer wavelengths. We adopt a systematic approach to understand sub-band gap optical absorption in hyper-doped silicon. We provided a diagnosis of hyper-doped silicon's potential to achieve the Army's goal of 100% situational awareness, especially in the shortwave-infrared portion of the optical spectrum. Specifically, we performed multiple-wavelength spectroscopy to determine the location and bandwidth of states within hyper-doped silicon's band gap; contact-less measurements of carrier concentration to determine whether sub-band gap photon absorption generates mobile carriers; and measurements of the photo-excited carriers transport properties. Using this knowledge, we provide an assessment for hyper-doped silicon as a potential sensor material at wavelengths important to specific Army operational goals, including eye-safe operation (lambda approx. 1550 nm), replacement of InGaAs (lambda less than 1700 nm), and other applications (lambda greater than 2000 nm).

Document Details

Document Type

Technical Report

Publication Date

Mar 20, 2012

Accession Number

ADA584425

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