The Role of Ion Track Structure on High-Injection Carrier Dynamics in High-Speed Si and III-V Optoelectronic Sensors

Laird, J.S.; Onoda, Shinobu; Hirao, Toshio; Edmonds, Larry D.; Ohshima, Takeshi

doi:10.1109/tns.2007.911421

Cited by 9 publications

(6 citation statements)

References 40 publications

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“…According to Mavis et al, the collection depth in similar 180 nm structures is m i.e., the maximum possible QNR is m. This translates into a zeroth order solution (the longest duration component in the Fourier series shown in (2)) at least 100 times faster than the 1-2 ns observed in the --Si diodes discussed above [15], [17]. For the structures found in the NMOS regions, the ambipolar period of charge collection is even faster due to the higher minority carrier diffusivity (electrons).…”

Section: B Case For Cmos Invertermentioning

confidence: 92%

“…These screening effects lengthen the pulse width by a degree which depends on device structure, track characteristics and minority carrier diffusivity [7], [15]. Understanding the relative roles of drift and diffusion in determining the pulse shape is important if the effect of temperature on pulse width is to be properly understood.…”

Section: A Diffusion Controlled Drift Transportmentioning

confidence: 99%

“…The camera can also be used to correct for any thermal expansion in the beam axis using the automated XYZ stage to maintain focus at the same position. Maintaining focus is critical as spot size not only determines image resolution but the transient current pulse shape in some device structures [15], [17]. Average laser energy and LET are measured using a Thorlabs (PM-100 and S130A detector) mounted at a fiducial point on the sample stage.…”

Section: B Picosecond Laser System For Temperature Analysesmentioning

confidence: 99%

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Temperature Dependence of Spatially Resolved Picosecond Laser Induced Transients in a Deep Submicron CMOS Inverter

Laird

Yuan

et al. 2009

IEEE Trans. Nucl. Sci.

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Spatially-resolved picosecond laser induced transients have been measured in a 0.18 m CMOS inverter test structure as a function of temperature. Sensitive -drain and -drain nodes have been scaled in size to accommodate characteristic differences between ion and laser tracks. Images based on pulse characteristics have been collected from 325 K to 400 K and transient currents extracted from laser strikes to both the OFF drain and its surroundings. With increasing temperature strikes to the OFF drain result in a pulse width which appears to broadens whilst the charge collected surprisingly decreases.

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Section: B Case For Cmos Invertermentioning

confidence: 92%

Section: A Diffusion Controlled Drift Transportmentioning

confidence: 99%

Section: B Picosecond Laser System For Temperature Analysesmentioning

confidence: 99%

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Temperature Dependence of Spatially Resolved Picosecond Laser Induced Transients in a Deep Submicron CMOS Inverter

Laird

Yuan

et al. 2009

IEEE Trans. Nucl. Sci.

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“…The low-resistance of these junctions has strong ramifications for remote-LBIC imaging. The minority carriers inside the plasma column are screened by the majority carriers and a small drift and longitudinal diffusion current exist to remove this charge [39,40].…”

Section: Principles Of Lbicmentioning

confidence: 99%

Laser-beam-induced current microscopy of electric fields in natural minerals caused by impurity zonation and structural defects

Laird¹,

Johnson²,

Ryan³

2012

Meas. Sci. Technol.

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Regions of band-bending in semiconducting sulfide minerals are thought to drive both electrochemical reactions with passing fluids resulting in precious metal ore genesis in undersaturated solutions, and bacterial oxidation by ferro-oxidans. Better understanding the role of these regions and their surface texturing on likely seeding spots and growth/dissolution rates requires large scale imaging of regions sustaining these fields. In this paper, we describe a system and methodology based on a scanning laser microscope technique called laser-beam-induced current (LBIC) for imaging fields in natural sulfides. The technique is illustrated on a synthetic junction fabricated using Au and Pt Schottky barriers on natural cubic pyrite, followed by an initial scope on a natural chalcopyrite assemblage. Different modes of LBIC imaging are discussed in light of complexity within real mineral assemblages. The remote contact mode is found to be ideal for natural samples and reasons for this conclusion are detailed.

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“…It is also reported [34] that the charge collection dynamics in the semiconductor is similar, no matter whether the EHP plasma is generated by femtosecond laser or by an ion impact. The radial initial distribution of the EHP plasma is different for each mechanism; however, ambipolar expansion quickly compensates the geometrical differences [35]. Thus, for computational purposes, it can be said that the ion hit and the laser pulse creates similar transport dynamics in the device, provided that their total pair production are the same [5]: Z g las ðr; z; tÞ dV dt ¼ Z g ion ðr; z; tÞ dV dt ð23Þ…”

Section: Heavy Ion Models In Tcad Sentaurusmentioning

confidence: 99%

Simulation of femtosecond pulsed laser effects on MOS electronics using TCAD Sentaurus customized models

Palomo

Fernández-Martínez

Mogollon

et al. 2010

Int J Numerical Modelling

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SUMMARYPulsed laser illumination constitutes an excellent tool to emulate the effects produced by the impact of highly energetic particles on electronic circuits. Numerical simulation techniques could be used to study these effects and to establish accurate relationships between the laser parameters and the particle characteristics. Unfortunately, although particle incidence can be accurately simulated, up to now, there not exist a simulation technique able to reproduce completely the effects in electronics produced by a femtosecond pulsed laser. In this paper, we explore the Synopsys Sentaurus TCAD ability to simulate the effects of pulsed laser illumination. Theoretical study of the physics of the laser-semiconductor interactions leads us to design a new simulation tool. Modifying the heavy ion generation rate included in Sentaurus TCAD, we can take into account all the theoretical predicted characteristics of femtosecond laser illumination, and reproduce the single event effects (SEE) found in experimental tests.

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The Role of Ion Track Structure on High-Injection Carrier Dynamics in High-Speed Si and III-V Optoelectronic Sensors

Cited by 9 publications

References 40 publications

Temperature Dependence of Spatially Resolved Picosecond Laser Induced Transients in a Deep Submicron CMOS Inverter

Temperature Dependence of Spatially Resolved Picosecond Laser Induced Transients in a Deep Submicron CMOS Inverter

Laser-beam-induced current microscopy of electric fields in natural minerals caused by impurity zonation and structural defects

Simulation of femtosecond pulsed laser effects on MOS electronics using TCAD Sentaurus customized models

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