Analysis of the dependence of critical electric field on semiconductor bandgap

Slobodyan, Oleksiy; Flicker, Jack; Dickerson, Jeramy Ray; Shoemaker, Jonah; Binder, Andrew; Smith, Trevor; Goodnick, Stephen M.; Kaplar, Robert; Hollis, M.A.

doi:10.1557/s43578-021-00465-2

Cited by 25 publications

(11 citation statements)

References 56 publications

(114 reference statements)

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“…In general, the ionization rates for electrons and holes are different in a semiconductor due to their inherent differences in the ability to ionize an atom during collisions (Arnold & Oelgart, 1984; Chynoweth, 1958). The determination of ionization potential is important for estimating the critical electric field (maximum electric field responsible for avalanche breakdown due to carrier induced impact‐ionization) and the breakdown voltage of the DUT (Hamad, Raynaud, et al, 2015; Slobodyan et al, 2022; Wolff, 1954). The group used a UV laser as the light source for the OBIC measurements and utilized Shockley model to determine ionization rates from the multiplication coefficient.…”

Section: Microscopic Measurements Of Obicmentioning

confidence: 99%

An insight into optical beam induced current microscopy: Concepts and applications

Zhuo

Banik

Kao

et al. 2022

Microscopy Res & Technique

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Laser scanning optical beam induced current (OBIC) microscopy has become a powerful and nondestructive alternative to other complicated methods like electron beam induced current (EBIC) microscopy, for high resolution defect analysis of electronic devices. OBIC is based on the generation of electron–hole pairs in the sample due to the raster scanning of a focused laser beam with energy equal or greater than the band gap energy and synchronized detection of resultant current profile with respect to the beam positions. OBIC is particularly suitable to localize defect sites caused by metal–semiconductor interdiffusion or electrostatic discharge (ESD). OBIC signals, thus, are capable of revealing the parameters/factors directly related to the reliability and efficiency of the electronic device under test (DUT). In this review, the basic principles of OBIC microscopy strategies and their notable applications in semiconductor device characterization are elucidated. An overview on the developments of OBIC microscopy is also presented. Specifically, the recent progresses on the following three OBIC measurement strategies have been reviewed, which include continuous laser based single photon OBIC, pulsed laser based single photon OBIC, and multiphoton OBIC microscopy for three‐dimensional mapping of photocurrent response of electronic devices at high spatiotemporal resolution. Challenges and future prospects of OBIC in characterizing complex electronic devices are also discussed. Highlights Characterization of electronic device quality is of paramount importance. Optical beam induced current (OBIC) microscopy offers spatially resolved mapping of local electronic properties. This review presents the principle and notable applications of OBIC microscopy.

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Section: Microscopic Measurements Of Obicmentioning

confidence: 99%

An insight into optical beam induced current microscopy: Concepts and applications

Zhuo

Banik

Kao

et al. 2022

Microscopy Res & Technique

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“…Particularly, BFoM is related to the cubic of the critical electric field, itself related to the energy bandgap. The relationship between them is a power law dependence whose refinement is discussed in a recent study by Slobodyan et al [1]. The increase of the breakdown voltage promotes the UWBGS superior performance and breakdown voltage is directly related to the critical electric field.…”

Section: Introductionmentioning

confidence: 96%

Non-volatile tuning of normally-on and off states of deep depletion ZrO2/O-terminated high voltage diamond MOSFET

Soto

Couret

Canas

et al. 2023

Diamond and Related Materials

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“…Carrier multiplication in CCDs is a post-detection process. It can be realized during carrier transport under a strong electric field (~10 6 V/m) between adjacent depletion wells separated by the potential barrier with an approximate thickness of 1 μm [15] [16]. Therefore, carriers are often subjected to backscattering, recombination, and surface defects, leading to increased CTI.…”

Section: Introductionmentioning

confidence: 99%

Graphene Channel Electron-Multiplying Charge-Coupled Pixel

et al. 2023

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Traditional electron-multiplying charge-coupled devices suffer from slow readout and large power consumption because of the complex driving circuitry implemented for the square clocking to serially transfer the charge during the readout process. At the same time, the photo-generated carriers are also prone to pre-amplification losses. Owing to the electrostatic capacitive coupling of the tunable graphene channel with the silicon photogate, an in-situ transient photoresponse study of the single graphene-oxide-silicon heterostructure driven into pre-avalanche condition by a fast sinusoidal gating signal is presented. This technique paves the way for futuristic sinusoidally driven, graphene-based, out-of-plane electronmultiplication charge-coupled devices with specific low-power surveillance and adaptive optics applications. The operating scheme of the device demonstrates the excellent capability for sensing short and small bursts of photons (25 nW). The maximum multiplication factor of ∼ 8.5 and responsivity of 350 A/W are achieved. The operating equipment limitations and their respective solutions are also discussed.

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Analysis of the dependence of critical electric field on semiconductor bandgap

Cited by 25 publications

References 56 publications

An insight into optical beam induced current microscopy: Concepts and applications

An insight into optical beam induced current microscopy: Concepts and applications

Non-volatile tuning of normally-on and off states of deep depletion ZrO2/O-terminated high voltage diamond MOSFET

Graphene Channel Electron-Multiplying Charge-Coupled Pixel

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