Jonathan K.M. Chun scite author profile

Hydrofluoric acid solutions containing high concentrations of the ion NO+ produce an etchant capable of reproducibly generating a porous silicon layer on both single-crystal and polycrystalline silicon surfaces. Room-temperature photoluminescence from porous silicon that has been chemically etched in such solutions has been observed. The photoluminescent intensity is superior to that obtained using HNO3/HF based stain etches. Reproducibility with respect to etch induction time, and the quality of the porous silicon layer are also improved when compared to classic stain etchants. Although, prior work has suggested that HNO2 is the active oxidant in silicon stain etching processes, the present work points to NO+ as the active species.

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Nickel ferrocyanide modified electrodes as active cation-exchange matrices: real time XRD evaluation of overlayer structure and electrochemical behavior

Kelly

Arbuckle-Keil

Johnson

et al. 2001

Journal of Electroanalytical Chemistry

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A silicon sensor for SO2

Kelly

Chun

Bocarsly

1996

Nature

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General Brönsted Acid Behavior of Porous Silicon: A Mechanistic Evaluation of Proton-Gated Quenching of Photoemission from Oxide-Coated Porous Silicon

1997

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Photoinduced visible light emission from porous silicon can be reversibly quenched by a wide variety of chemical species. The growth of a thin layer of oxide on the porous silicon surface disrupts the quenching ability of most species, narrowing down the number of quenchers to include primarily those which act as Brönsted bases. Electron paramagnetic resonance spectroscopy, infrared spectroscopy, photoluminescence data, and surface chemistry suggest a quenching mechanism which involves the extraction of a nonspecifically attached proton in the oxide layer upon exposure to base. This proton is loosely affiliated with a surface defect of the P b type. This defect serves as a hole trap in the absence of a proton providing a nonradiative relaxation pathway. However, when a proton is present in the oxide layer, Coulombic interactions force the hole trap into a state which falls below the bandgap, allowing for efficient radiative recombination of electronhole pairs. The electron paramagnetic resonance spectroscopy data also demonstrate that there are at least two distinct mechanisms of luminescence quenching of porous silicon.

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Jonathan K.M. Chun

Proton gated emission from porous silicon

High efficiency chemical etchant for the formation of luminescent porous silicon

Nickel ferrocyanide modified electrodes as active cation-exchange matrices: real time XRD evaluation of overlayer structure and electrochemical behavior

A silicon sensor for SO2

General Brönsted Acid Behavior of Porous Silicon: A Mechanistic Evaluation of Proton-Gated Quenching of Photoemission from Oxide-Coated Porous Silicon

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