H. Cheng scite author profile

We report on high electric field stress measurements at room temperature on InAlN/AlN/GaN heterostructure field effect transistor structures. The degradation rate as a function of the average electron density in the GaN channel (as determined by gated Hall bar measurements for the particular gate biases used), has a minimum for electron densities around 1×1013 cm−2, and tends to follow the hot phonon lifetime dependence on electron density. The observations are consistent with the buildup of hot longitudinal optical phonons and their ultrafast decay at about the same electron density in the GaN channel. In part because they have negligible group velocity, the build up of these hot phonons causes local heating, unless they decay rapidly to longitudinal acoustic phonons, and this is likely to cause defect generation which is expected to be aggravated by existing defects. These findings call for modified approaches in modeling device degradation.

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Influence of N interstitials on the electronic properties of GaAsN alloys

Jin

Jock

Cheng

et al. 2009

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We have used rapid thermal annealing to investigate the influence of N interstitials on the electronic properties of GaAsN alloys. Nuclear reaction analysis reveals an annealing-induced decrease in the interstitial N concentration, while the total N composition remains constant. Corresponding signatures for the reduced interstitial N concentration are apparent in Raman spectra. Following annealing, both the room-T carrier concentration, n, and the mobility increase. At higher measurement-Ts, a thermally activated increase in n suggests the presence of a trap near GaAsN conduction band edge with activation energy 85±15 meV. The annealing-induced increase in n suggests the association of the trap with interstitial N.

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Characterization of short-pulse oscillators by means of a high-dynamic-range autocorrelation measurement

Braun

Rudd²,

Cheng³

et al. 1995

Opt. Lett.

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A high-dynamic-range autocorrelation technique was used to characterize the temporal pulse shape of ultrashort laser pulses produced from four separate oscillators. These lasers included two Kerr-lens mode-locked Ti:sapphire oscillators as well as a Nd:glass and a Ti:sapphire oscillator, each passively mode locked by an antiresonant Fabry-Perot semiconductor saturable absorber. It was shown that the Nd:glass oscillator supported a pulse that was temporally clean over 8 orders of magnitude.

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Micromachined circuits for millimeter- and sub-millimeter-wave applications

Katehi

Rebeiz

Weller

et al. 1993

IEEE Antennas Propag. Mag.

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H. Cheng

Pulsed laser deposited Be x Zn 1-x O 1-y S y quaternary alloy films: structure, composition, and band gap bowing

Degradation in InAlN/GaN-based heterostructure field effect transistors: Role of hot phonons

Influence of N interstitials on the electronic properties of GaAsN alloys

Characterization of short-pulse oscillators by means of a high-dynamic-range autocorrelation measurement

Micromachined circuits for millimeter- and sub-millimeter-wave applications

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