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214 results on '"del Alamo, Jesus A."'

1. Robust Chemiresistive Behavior in Conductive Polymer/MOF Composites

Author

Roh, Heejung, Kim, Dong-Ha, Cho, Yeongsu, Jo, Young-Moo, del Alamo, Jesús A., Kulik, Heather J., Dincă, Mircea, and Gumyusenge, Aristide

Subjects
Physics - Chemical Physics, Condensed Matter - Materials Science
Abstract

Metal-organic frameworks (MOFs) are promising materials for gas sensing but are often limited to single-use detection. We demonstrate a hybridization strategy synergistically deploying conductive MOFs (cMOFs) and conductive polymers (cPs) as two complementary mixed ionic-electronic conductors in high-performing stand-alone chemiresistors. Our work presents significant improvement in i) sensor recovery kinetics, ii) cycling stability, and iii) dynamic range at room temperature. We demonstrate the effect of hybridization across well-studied cMOFs based on 2,3,6,7,10,11-hexahydroxytriphenylene (HHTP) and 2,3,6,7,10,11-hexaiminotripphenylene (HITP) ligands with varied metal nodes (Co, Cu, Ni). We conduct a comprehensive mechanistic study to relate energy band alignments at the heterojunctions between the MOFs and the polymer with sensing thermodynamics and binding kinetics. Our findings reveal that hole enrichment of the cMOF component upon hybridization leads to selective enhancement in desorption kinetics, enabling significantly improved sensor recovery at room temperature, and thus long-term response retention. This mechanism was further supported by density functional theory calculations on sorbate-analyte interactions. We also find that alloying cPs and cMOFs enables facile thin film co-processing and device integration, potentially unlocking the use of these hybrid conductors in diverse electronic applications.

Published
2024

2. Neural Network Training with Asymmetric Crosspoint Elements

Author

Onen, Murat, Gokmen, Tayfun, Todorov, Teodor K., Nowicki, Tomasz, del Alamo, Jesus A., Rozen, John, Haensch, Wilfried, and Kim, Seyoung

Subjects
Computer Science - Machine Learning, Computer Science - Emerging Technologies, Electrical Engineering and Systems Science - Systems and Control
Abstract

Analog crossbar arrays comprising programmable nonvolatile resistors are under intense investigation for acceleration of deep neural network training. However, the ubiquitous asymmetric conductance modulation of practical resistive devices critically degrades the classification performance of networks trained with conventional algorithms. Here, we describe and experimentally demonstrate an alternative fully-parallel training algorithm: Stochastic Hamiltonian Descent. Instead of conventionally tuning weights in the direction of the error function gradient, this method programs the network parameters to successfully minimize the total energy (Hamiltonian) of the system that incorporates the effects of device asymmetry. We provide critical intuition on why device asymmetry is fundamentally incompatible with conventional training algorithms and how the new approach exploits it as a useful feature instead. Our technique enables immediate realization of analog deep learning accelerators based on readily available device technologies.

Published
2022

4. Multiscale Metrology and Optimization of Ultra-Scaled InAs Quantum Well FETs

Author

Kharche, Neerav, Klimeck, Gerhard, Kim, Dae-Hyun, del Alamo, Jesús. A., and Luisier, Mathieu

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

A simulation methodology for ultra-scaled InAs quantum well field effect transistors (QWFETs) is presented and used to provide design guidelines and a path to improve device performance. A multiscale modeling approach is adopted, where strain is computed in an atomistic valence-force-field method, an atomistic sp3d5s* tight-binding model is used to compute channel effective masses, and a 2-D real-space effective mass based ballistic quantum transport model is employed to simulate three terminal current-voltage characteristics including gate leakage. The simulation methodology is first benchmarked against experimental I-V data obtained from devices with gate lengths ranging from 30 to 50 nm. A good quantitative match is obtained. The calibrated simulation methodology is subsequently applied to optimize the design of a 20 nm gate length device. Two critical parameters have been identified to control the gate leakage magnitude of the QWFETs, (i) the geometry of the gate contact (curved or square) and (ii) the gate metal work function. In addition to pushing the threshold voltage towards an enhancement mode operation, a higher gate metal work function can help suppress the gate leakage and allow for much aggressive insulator scaling.

Published
2010
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5. Inquiry-Learning with WebLab: Undergraduate Attitudes and Experiences

Author

Fischer, Judith, Mitchell, Rudolph, and del Alamo, Jesus

Abstract

The Microelectronics WebLab at MIT allows students to do actual (not simulated) laboratory research on state-of-the art equipment through the Internet. This study assesses the use of WebLab in a junior-level course on microelectronic devices and circuits in 2004-05 and 2005-06. In quantitative surveys and qualitative interviews, students and faculty reported that WebLab was effective as an instrument of learning, and grew more so with refinements of the program. WebLab allowed undergraduates to learn at their own pace and on their own schedules. It enabled them to use different processes of learning (intuitive, visual, abstract), and it gave them an opportunity to link individual and collaborative effort in creative combinations. Online laboratories on this model have broad applications in the experimental sciences and in other research-oriented disciplines.

Published
2007
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9. Nanometer-Scale III-V MOSFETs

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Del Alamo, Jesus A, Antoniadis, Dimitri A, Lin, Jianqiang, Lu, Wenjie, Vardi, Alon, Zhao, Xin, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Del Alamo, Jesus A, Antoniadis, Dimitri A, Lin, Jianqiang, Lu, Wenjie, Vardi, Alon, and Zhao, Xin

Abstract

© 2013 IEEE. After 50 years of Moore's Law, Si CMOS, the mainstream logic technology, is on a course of diminishing returns. The use of new semiconductor channel materials with improved transport properties over Si offer the potential for device scaling to nanometer dimensions and continued progress. Among new channel materials, III-V compound semiconductors are particularly promising. InGaAs is currently the most attractive candidate for future III-V based n-type MOSFETs while InGaSb is of great interest for p-channel MOSFETs. At the point of most likely deployment, devices based on these semiconductors will have a highly three-dimensional architecture. This paper reviews recent progress toward the development of nanoscale III-V MOSFETs based on InGaAs and InGaSb with emphasis on scalable technologies and device architectures and relevant physics. Progress in recent times has been brisk but much work remains to be done before III-V CMOS can become a reality.

Published
2021

10. Excess Off-State Current in InGaAs FinFETs

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Zhao, Xin, Vardi, Alon, del Alamo, Jesus A, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Zhao, Xin, Vardi, Alon, and del Alamo, Jesus A

Abstract

We present a detailed study of the off-state leakage current in scaled self-aligned InGaAs FinFETs. In long-channel devices, band-to-band tunneling at the drain-end of the channel is shown to be the root cause of excessive off-state current. This conclusion emerges from its characteristic electric field and temperature behavior and the absence of gate length and fin width dependencies. In short-channel devices, off-state current is significantly larger and it increases as the gate length shortens or the fin widens. We attribute this behavior to current multiplication through the gain of a floating-base parasitic bipolar transistor that is present inside the MOSFET. We extract the bipolar current gain which in short-channel devices is found to increase as the gate length shortens and decrease as the fin width narrows. In long channel devices, the current gain drops exponentially due to base recombination. This has allowed us to extract the diffusion length of electrons in the body of the transistor., DTRA (Grant HDTRA1-14-1-0057), NSF (Grant 0959514)

Published
2021

11. Time-Dependent Dielectric Breakdown Under AC Stress in GaN MIS-HEMTs

Author

Massachusetts Institute of Technology. Microsystems Technology Laboratories, Lee, Ethan S, Hurtado, Luis, Joh, Jungwoo, Krishnan, Srikanth, Pendharkar, Sameer, del Alamo, Jesus A, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Lee, Ethan S, Hurtado, Luis, Joh, Jungwoo, Krishnan, Srikanth, Pendharkar, Sameer, and del Alamo, Jesus A

Abstract

We investigate time-dependent dielectric breakdown (TDDB) in AlGaN/GaN Metal-Insulator-Semiconductor High Electron Mobility Transistors (MIS-HEMTs) under forward bias AC stress which better emulates real-world operational conditions. To this end, we have performed TDDB experiments across a wide range of frequencies, temperatures, and recovery voltage levels. We find that TDDB under AC stress shows longer breakdown times than under DC stress and that this increase is more prominent with higher frequency, lower temperature, and more negative recovery voltage. We hypothesize that this is due to the dynamics of the gate stack in GaN MIS-HEMTs biased with a high positive gate voltage. Under these conditions, a second electron channel forms at the dielectric/AlGaN interface. This process is relatively slow as these electrons come from the 2DEG at the AlGaN/GaN interface and must overcome the energy barrier presented by the AlGaN. At the same gate voltage then, the electric field across the gate oxide is lower in magnitude under AC stress at high enough frequency than under DC stress explaining the obtained results.

Published
2021

12. Nanometre-scale electronics with III-V compound semiconductors

Author

del Alamo, Jesus A.

Subjects
Semiconductors -- Properties, Nanoparticles -- Electric properties, Miniature electronic equipment -- Forecasts and trends -- Models, Microelectronics -- Forecasts and trends -- Models, Market trend/market analysis, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

For 50 years the exponential rise in the power of electronics has been fuelled by an increase in the density of silicon complementary metal-oxide-semiconductor (CMOS) transistors and improvements to their logic performance. But silicon transistor scaling is now reaching its limits, threatening to end the microelectronics revolution. Attention is turning to a family of materials that is well placed to address this problem: group III-V compound semiconductors. The outstanding electron transport properties of these materials might be central to the development of the first nanometre-scale logic transistors., The microelectronics revolution might best be characterized by the motto 'smaller is better'. A unique attribute of the silicon metal-oxide-semiconductor field-effect transistor (MOSFET), the workhorse of the industry, is that [...]

Published
2011
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13. Lateral and vertical scaling of [In.sub. 0.7] [Ga. sub. 0.3] As HEMTs for post-Si-CMOS logic applications

Author

Dae-Hyun Kim and del Alamo, Jesus A.

Subjects
Gallium arsenide semiconductors -- Structure, Gallium arsenide semiconductors -- Evaluation, High-electron-mobility transistors -- Evaluation, Indium -- Mechanical properties, Indium -- Electric properties, Business, Electronics, Electronics and electrical industries
Abstract

The gate-length and insulator-thickness scaling behavior of InGaAs HEMTs onto their logic performance is investigated. Both experimental and theoretical work carried out confirms that insulator-thickness scaling is necessary to achieve sub-100-nm gate-length InGaAs HEMTs and decreasing the barrier thickness improves the cutoff frequency.

Published
2008

14. Logic suitability of 50-nm [In.sub.0.7][Ga.sub.0.3]As HEMTs for beyond-CMOS applications

Author

Dae-Hyun Kim, del Alamo, Jesus A., Jae-Hak Lee, and Kwang-Seok Seo

Subjects
Complementary metal oxide semiconductors -- Electric properties, High-electron-mobility transistors -- Design and construction, Nanotechnology -- Research, Business, Electronics, Electronics and electrical industries
Abstract

The suitability of nanometer-scale InGaAs high-electron mobility transistors (HEMTs) as an n-channel device is examined for a future high-speed and low-power logic technology for beyond CMOS applications. Findings reveal that nonoptimized 50-nm InGaAs HEMTs with a buried-Pt gate exhibit promising logic characteristics.

Published
2007

15. Anomalous Source-Side Degradation of InAlN/GaN HEMTs Under High-Power Electrical Stress

Author

Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Singapore-MIT Alliance in Research and Technology (SMART), Wu, Yufei, Sasangka, Wardhana A., del Alamo, Jesus A, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Singapore-MIT Alliance in Research and Technology (SMART), Wu, Yufei, Sasangka, Wardhana A., and del Alamo, Jesus A

Abstract

The electrical degradation of InAlN/GaN high-electron-mobility transistors for millimeter-wave applications has been examined under simultaneous high V [subscript DS,stress] and high I[subscript Dstress] electrical stress. Besides a drain current decrease and a positive threshold voltage shift, the creation of an anomalous source-side gate leakage path has been identified. We attribute this to high electric-field induced trap generation in the AlN layer directly under the gate edge on the source side. The resulting increase in gate leakage further exacerbates the degradation of the gate diode. In addition, we postulate that high-power stress leads to significant device self-heating that causes gate sinking and leads to a permanent positive threshold voltage shift and drain current degradation.

Published
2020

16. Time-Dependent Dielectric Breakdown in High-Voltage GaN MIS-HEMTs: The Role of Temperature

Author

Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lincoln Laboratory, Warnock, Shireen M., Lemus, Allison, Joh, Jungwoo, Krishnan, Srikanth, Pendharkar, Sameer, del Alamo, Jesus A, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lincoln Laboratory, Warnock, Shireen M., Lemus, Allison, Joh, Jungwoo, Krishnan, Srikanth, Pendharkar, Sameer, and del Alamo, Jesus A

Abstract

We have investigated time-dependent dielectric breakdown in high-voltage AlGaN/GaN metal-insulator-semiconductor high-electron mobility transistors, with a focus specifically on the role of temperature under positive gate stress conditions. We aim toward understanding the temperature dependence of progressive breakdown (PBD) as well as hard breakdown. We find that the temperature dependence of time-to-first breakdown, hard breakdown, and the gate current evolution during PBD all share similar, shallow activation energies that suggest a common underlying mechanism. However, the gate current noise during PBD seems to be independent of temperature and is likely due to a tunneling process. Understanding of temperature-dependent breakdown is essential to developing accurate device lifetime estimates.

Published
2020

17. Comprehensive dynamic on-resistance assessments in GaN-on-Si MIS-HEMTs for power switching applications

Author

Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Chou, Po-Chien, Hsieh, Ting-En, Cheng, Stone, del Alamo, Jesus A, Chang, Edward Yi, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Chou, Po-Chien, Hsieh, Ting-En, Cheng, Stone, del Alamo, Jesus A, and Chang, Edward Yi

Abstract

This study comprehensively analyzed the reliability of trapping and hot-electron effects responsible for the dynamic on-resistance (Ron) of GaN-based metal–insulator–semiconductor high electron mobility transistors. Specifically, this study performed the following analyses. First, we developed the on-the-fly Ron measurement to analyze the effects of traps during stress. With this technique, the faster one (with a pulse period of 20 ms) can characterize the degradation; the transient behavior could be monitored accurately by such short measurement pulse. Then, dynamic Ron transients were investigated under different bias conditions, including combined off state stress conditions, back-gating stress conditions, and semi-on stress conditions, in separate investigations of surface- and buffer-, and hot-electron-related trapping effects. Finally, the experiments showed that the Ron increase in semi-on state is significantly correlated with the high drain voltage and relatively high current levels (compared with the off-state current), involving the injection of greater amount of hot electrons from the channel into the AlGaN/insulator interface and the GaN buffer. These findings provide a path for device engineering to clarify the possible origins for electron traps and to accelerate the development of emerging GaN technologies.

Published
2020

18. Scaling Effects on Single-Event Transients in InGaAs FinFETs

Author

Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Gong, Huiqi, Ni, Kai, Zhang, En Xia, Sternberg, Andrew L., Kozub, John A., Ryder, Kaitlyn L., Keller, Ryan F., Ryder, Landen D., Weiss, Sharon M., Weller, Robert A., Alles, Michael L., Reed, Robert A., Fleetwood, Daniel M., Schrimpf, Ronald D., Vardi, Alon, del Alamo, Jesus A, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Gong, Huiqi, Ni, Kai, Zhang, En Xia, Sternberg, Andrew L., Kozub, John A., Ryder, Kaitlyn L., Keller, Ryan F., Ryder, Landen D., Weiss, Sharon M., Weller, Robert A., Alles, Michael L., Reed, Robert A., Fleetwood, Daniel M., Schrimpf, Ronald D., Vardi, Alon, and del Alamo, Jesus A

Abstract

The single-event-transient response of InGaAs FinFETs with different fin widths is examined using pulsed-laser and heavy-ion irradiation. Devices with wider fins collect more charge in both environments. Quantum-well structures confine charge collection in the channel, and determine the sensitive volume. Simulations show that the charge density produced by irradiation is similar for devices with different fin widths, but more charge is collected by wider fin devices due to the larger channel volume. Charge accumulated in the buffer and substrate layers modulates the body potential, altering the degree of back-gate control, leading to additional effects associated with charge accumulation in wider fin devices. Optical simulations for a model system suggest that optical phenomena in the fins should be considered for laser testing. These include optical interference, plasmonic enhancement at the metal-dielectric interfaces, and enhanced electron-hole pair recombination due to multiple reflections in multigate devices with nanoscale dimensions.

Published
2020

19. Alcohol-Based Digital Etch for III–V Vertical Nanowires With Sub-10 nm Diameter

Author

Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lu, Wenjie, Zhao, Xin, Choi, Dongsung, El Kazzi, Salim, del Alamo, Jesus A, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Lu, Wenjie, Zhao, Xin, Choi, Dongsung, El Kazzi, Salim, and del Alamo, Jesus A

Abstract

This letter introduces a novel alcohol-based digital etch technique for III-V FinFET and nanowire MOSFET fabrication. The new technique addresses the limitations of the conventional water-based approach in enabling structures with sub-10-nm 3-D features. Using the same oxidation step, the new technique shows an etch rate of 1 nm/cycle, identical to the conventional approach. Sub-10 nm fins and nanowires with a high mechanical yield have been achieved. InGaAs nanowires with a diameter of 5 nm and an aspect ratio greater than 40 have been demonstrated. The new technique has also been successfully applied to InGaSb-based heterostructures, the first demonstration of digital etch in this material system. Vertical InGaAs nanowire gate-all-around MOSFETs with a subthreshold swing of 70 mV/decade at V DS = 50 mV have been obtained at a nanowire diameter of 40 nm, demonstrating the good interfacial quality that the new technique provides.

Published
2020

20. Gate current degradation in W-band InAlN/AlN/GaN HEMTs under gate stress

Author

Massachusetts Institute of Technology. Microsystems Technology Laboratories, Wu, Yufei, del Alamo, Jesus A, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Wu, Yufei, and del Alamo, Jesus A

Abstract

Schottky gate degradation of W-band InAlN/AlN/GaN high-electron-mobility transistors (HEMTs) has been studied under prolonged positive gate stress. Two different degradation mechanisms have been identified. In an early stage, a gate leakage current increase takes place without any observable drain current nor source and drain resistance degradation. We propose electric field induced trap generation in the AlN barrier layer as the cause. Under harsher gate stress, a second degradation mechanism kicks in where gate leakage current, as well as drain current and the source and drain resistances degrade significantly. We attribute this to Schottky barrier degradation due to severe local self-heating., National Reconnaissance Office (Contract DII NRO000-13C0309)

Published
2020

21. Unified Mechanism for Positive- and Negative-Bias Temperature Instability in GaN MOSFETs

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Guo, Alex, del Alamo, Jesus A., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Guo, Alex, and del Alamo, Jesus A.

Abstract

We present a comprehensive study of bias temperature instability (BTI) in GaN MOSFETs under moderate positive and negative gate bias stress. We investigate the evolution of threshold voltage (V T ), maximum transconductance (g m,max ), and subthreshold swing (S). Our results show a universal continuous, symmetrical, and reversible VT shift and gm,max change as gate stress voltage (VGS,stress) increases from -5 to 5V at room temperature. The time evolution of V T is well described by a power law model. The voltage dependence, time dependence, and temperature dependence of our results suggest that for moderate gate bias stress, positive BTI and negative BTI are due to a single reversible mechanism. This is electron trapping/detrapping in preexisting oxide traps that form a defect band very close to the GaN/oxide interface and extend in energy beyond the conduction band edge of GaN and below the Fermi level at the channel surface at 0 V.

Published
2020

22. A Diamond:H/WO3 Metal–Oxide–Semiconductor Field-Effect Transistor

Author

Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Yin, Zongyou, Tordjman, Moshe, Vardi, Alon, Kalish, Rafi, del Alamo, Jesus A, Massachusetts Institute of Technology. Microsystems Technology Laboratories, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Yin, Zongyou, Tordjman, Moshe, Vardi, Alon, Kalish, Rafi, and del Alamo, Jesus A

Abstract

A p-type Diamond:H/WO 3 metal-oxide-semiconductor field-effect transistor (MOSFET) based on surface transfer doping is demonstrated. Using a low-temperature ALD-grown HfO 2 as gate insulator, the Diamond:H/WO 3 MOSFETs show excellent output characteristics, gate-controllable 2-D hole gas, and low gate leakage current. Long-channel FETs exhibit improved subthreshold behavior but reduced transconductance with respect to short-channel devices. An observed WO 3 -thickness-dependent threshold voltage is consistent with enhanced surface transfer doping as the WO 3 layer is thinned down. Low-temperature measurements suggest a significantly lower mobility than expected in this material system. This illustrates the challenge of maintaining high TMO quality during device fabrication.

Published
2020

23. Sub-10-nm-Diameter InGaAs Vertical Nanowire MOSFETs: Ni Versus Mo Contacts

Author

Lincoln Laboratory, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Zhao, Xin, Heidelberger, Christopher, Fitzgerald, Eugene A, Lu, Wenjie, Vardi, Alon, del Alamo, Jesus A, Lincoln Laboratory, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Zhao, Xin, Heidelberger, Christopher, Fitzgerald, Eugene A, Lu, Wenjie, Vardi, Alon, and del Alamo, Jesus A

Abstract

Recently, sub-10-nm-diameter InGaAs vertical nanowire (VNW) MOSFETs have been demonstrated. The key to this achievement was the use of Ni for the top ohmic contact. In this paper, we present a detailed study of the impact of Ni and Mo contacts on the electrical characteristics of highly scaled InGaAs VNW MOSFETs. Sequential annealing experiments are presented that reveal the optimum temperature for each type of contact. A negative temperature dependence of the ON-resistance of 7-nm-diameter Ni-contacted devices suggests the existence of an energy barrier. We also observe an unexpected transconductance and drain-induced barrier loweirng (DIBL) dependence on transistor diameter in Ni-contacted devices as well as abnormal DIBL asymmetry to swapping source and drain. All these results can be explained by Ni diffusing down the nanowire during the contact annealing process, reducing the effective channel length, and creating a Schottky-barrier drain.

Published
2020

24. Impact of substrate-surface potential on the performance of RF power LDMOSFETs on high-resistivity SOI

Author

Scholvin, Jorg, Fiorenza, James G., and Del Alamo, Jesus A.

Subjects
Metal oxide semiconductor field effect transistors -- Design and construction, Silicon-on-isolator -- Methods, Power semiconductor devices -- Design and construction, Business, Electronics, Electronics and electrical industries
Abstract

The effects of substrate-surface potential on the RF power performance of laterally diffused MOSFETs (LDMOSFETs) fabricated on high-resistivity silicon-on-insulator (HR-SOI) is studied in detail. Substrate-surface inversion and accumulation substantially degrade the RF power performance of these devices with the help of an RF shunt between source and drain through the substrate surface.

Published
2006

26. Positive temperature coefficient of impact ionization in strained-Si

Author

Waldron, Niamh S., Pitera, Arthur J., Lee, Minjoo L., Fitzgerald, Eugene A., and del Alamo, Jesus A.

Subjects
Semiconductor wafers -- Electric properties, Semiconductor doping -- Research, Ionization -- Analysis, Business, Electronics, Electronics and electrical industries
Abstract

Impact ionization (II) in the strained Si layer of a strained-Si/SiGe heterostructure is studied. The finding states that the impact ionization multiplication coefficient has a positive temperature coefficient, which is opposite to that of bulk Si.

Published
2005

27. Experimental comparison of RF power LDMOSFETs on thin-film SOI and bulk silicon

Author

Fiorenze, James G. and Del Alamo, Jesus A.

Subjects
Silicon-on-isolator -- Analysis, Dielectric films -- Analysis, Thin films -- Analysis, Metal oxide semiconductor field effect transistors -- Analysis, Business, Electronics, Electronics and electrical industries
Abstract

Lateral double-diffused MOSFETs (LDMOSFETs) are fabricated on bulk silicon and thin-film silicon-on-insulator (SOI) wafers and their characteristics are compared. The comparison of a thin-film SOI LDMOSFET to a proven radio frequency (RF) power technology demonstrates the promise of a thin-film SOI technology for future highly integrated RF power applications.

Published
2002

29. Physical mechanisms limiting the manufacturing uniformity of millimeter-wave power InP HEMT's

Author

Krupenin, S., Blanchard, Roxann R., Somerville, M.H., Del Alamo, Jesus, Duh, K.G., and Chao, P.C.

Subjects
High-electron-mobility transistors -- Research, Business, Electronics, Electronics and electrical industries
Abstract

A method of diagnosing the physical mechanisms that limit manufacturing uniformity of millimeter-wave power InAIAs/InGaAs high electron mobility transistors on InP is presented.

Published
2000

30. A physical model for the kink effect in InA1As/InGaAs HEMT's

Author

Somerville, Mark H, Ernst, Alexander, and del Alamo, Jesus A.

Subjects
High-electron-mobility transistors -- Research, Business, Electronics, Electronics and electrical industries
Abstract

A model for the kink effect in InA1As/InGaAs HEMTs is presented.

Published
2000

31. Impact of high-power stress on dynamic ON-resistance of high-voltage GaN HEMTs

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Microsystems Technology Laboratories, del Alamo, Jesus, Jin, Donghyun, del Alamo, Jesus A, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Microsystems Technology Laboratories, del Alamo, Jesus, Jin, Donghyun, and del Alamo, Jesus A

Abstract

We have investigated the impact of high-power (HP) stress on the dynamic ON-resistance (RON) in high-voltage GaN High-Electron-Mobility Transistors (HEMTs). We use a newly proposed dynamic RON measurement methodology which allows us to observe RON transients after an OFF-to-ON switching event from 200 ns up to any arbitrary length of time over many decades. We find that HP-stress results in much worsened dynamic RON especially in the sub-ms range with minor changes on a longer time scale. We attribute this to stress-induced generation of traps with relatively short time constants. These findings suggest that accumulated device operation that reaches out to the HP state under RF power or hard-switching conditions can result in undesirable degradation of dynamic RON on a short time scale., United States. Advanced Research Projects Agency-Energy. Agile Delivery of Electrical Power Technology, Semiconductor Research Corporation, United States. Office of Naval Research. Design-for-Reliability Initiative for Future Technologies. Multidisciplinary University Research Initiative (ONR Grant)

Published
2017

32. Ultralow Resistance Ohmic Contacts for p-Channel InGaSb Field-Effect Transistors

Author

Guo, Luke W., Bennett, Brian R., Boos, John Brad, Del Alamo, Jesus A., Lu, Wenjie, del Alamo, Jesus A., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Microsystems Technology Laboratories, del Alamo, Jesus A., Guo, Luke W., and Lu, Wenjie

Subjects
Materials science, Condensed matter physics, Annealing (metallurgy), business.industry, Contact resistance, Electrical engineering, Omega, Electronic, Optical and Magnetic Materials, Electrical resistivity and conductivity, MOSFET, Field-effect transistor, Electrical and Electronic Engineering, business, Ohmic contact, Sheet resistance
Abstract

We demonstrate ultralow ohmic contact resistance to antimonide-based, p-channel quantum-well field-effect transistor (QW-FET) structures using a new p[superscript ±]-InAs/InAsSb cap structure. The incorporation of a p[superscript ±]-InAsSb layer enables the use of a thicker cap with lower sheet resistance, resulting in an improved contact resistivity. Using a Pd-based ohmic scheme, the composite cap structure resulted in a 4x reduction in contact resistance compared with a standard p[superscript ±]-InAs cap. This translates into nearly 3x improvement in the gm of fabricated InGaSb p-channel QW-FETs. Furthermore, Ni contacts on the composite cap were fabricated and a contact resistance of 45 Ω · μm was obtained. An accurate contact resistivity extraction in this very low range is possible through nanotransmission line models with sub-100 nm contacts. In devices of this kind with Ni-based contacts, we derive an ultralow contact resistivity of 5.2 · 10[superscript -8] Ω · cm[superscript 2]., Samsung (Firm), Intel Corporation

Published
2015

33. A new Z11 impedance technique to extract mobility and sheet carrier concentration in HFET's and MESFET's

Author

Ernst, Alexander N., Somerville, Mark H., and del Alamo, Jesus A.

Subjects
Field-effect transistors -- Research, Semiconductors -- Research, Business, Electronics, Electronics and electrical industries
Abstract

An accurate method has been devised to measure gate-to-source impedance in high performance heterostructure field-effect transistors. The method takes account of drain floating across a wide frequency spectrum and extracts channel resistance and gate capacitance. The measurement of the distributed semiconductor device InAlAs/InGaAs on InP HFET's is described.

Published
1998

34. A Si-Compatible Fabrication Process for Scaled Self-Aligned InGaAs FinFETs

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Vardi, Assaf, Lin, Jian, Lu, W., Zhao, X., Fernando Saavedra, Amalia Luisa, del Alamo, Jesus A, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Vardi, Assaf, Lin, Jian, Lu, W., Zhao, X., Fernando Saavedra, Amalia Luisa, and del Alamo, Jesus A

Abstract

We have developed a scalable gate-last process to fabricate self-aligned InGaAs FinFETs that relies on extensive use of dry etch. The process involves F-based dry etching of refractory metal ohmic contacts that are formed early in the process. The fins are etched in a novel inductive coupled plasma process using BCl[subscript 3]/SiCl[subscript 4]/Ar. High aspect ratio fins with smooth sidewalls are obtained. To further improve the quality of the sidewalls and shrink the fin width, digital etch is used. Through this process flow, we have demonstrated FinFETs with L[subscript g] = 20 nm and fin width as narrow as 7 nm with high yield. Good electrostatic characteristics are obtained in a wide range of device dimensions. In devices with 7 nm fin width, record channel aspect ratio, and transconductance per unit footprint are obtained., United States. Defense Threat Reduction Agency (Grant HDTRA1-14-1-0057), National Science Foundation (U.S.) (Grant E3S-STC-0939514)

Published
2019

35. Mesa-sidewall gate leakage in InAlAs/InGaAs heterostructure field-effect transistors

Author

Bahl, Sandeep R., Leary, Michael H., and del Alamo, Jesus A.

Subjects
Field-effect transistors -- Research, Gates (Electronics) -- Research, Business, Electronics, Electronics and electrical industries
Abstract

A study was conducted on the existence of a parasitic gate-leakage path in InAlAs/InGaAs heterostructure field-effect transistors fabricated by mesa isolation. The path was found to be formed by the low Schottky contact of the exposed channel edge with the gate metallizaton. The sidewall leakage was attributed to the crystallographic orientation of the sidewall and was observed to increase with channel thickness, sidewall overlap area and InAs mole fraction in the channel. The leakage was also found to increase the subthreshold and forward gate leakage currents and reduce the breakdown voltage.

Published
1992

36. Ultralow Resistance Ohmic Contacts for p-Channel InGaSb Field-Effect Transistors

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Microsystems Technology Laboratories, del Alamo, Jesus A., Guo, Luke W., Lu, Wenjie, Bennett, Brian R., Boos, John Brad, Del Alamo, Jesus A., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Microsystems Technology Laboratories, del Alamo, Jesus A., Guo, Luke W., Lu, Wenjie, Bennett, Brian R., Boos, John Brad, and Del Alamo, Jesus A.

Abstract

We demonstrate ultralow ohmic contact resistance to antimonide-based, p-channel quantum-well field-effect transistor (QW-FET) structures using a new p[superscript ±]-InAs/InAsSb cap structure. The incorporation of a p[superscript ±]-InAsSb layer enables the use of a thicker cap with lower sheet resistance, resulting in an improved contact resistivity. Using a Pd-based ohmic scheme, the composite cap structure resulted in a 4x reduction in contact resistance compared with a standard p[superscript ±]-InAs cap. This translates into nearly 3x improvement in the gm of fabricated InGaSb p-channel QW-FETs. Furthermore, Ni contacts on the composite cap were fabricated and a contact resistance of 45 Ω · μm was obtained. An accurate contact resistivity extraction in this very low range is possible through nanotransmission line models with sub-100 nm contacts. In devices of this kind with Ni-based contacts, we derive an ultralow contact resistivity of 5.2 · 10[superscript -8] Ω · cm[superscript 2]., Samsung (Firm), Intel Corporation

Published
2016

42. Enhanced transport in transistor by tuning transition-metal oxide electronic states interfaced with diamond

Author

Yin, Zongyou, Tordjman, Moshe, Lee, Youngtack, Vardi, Alon, Kalish, Rafi, del Alamo, Jesus A., Yin, Zongyou, Tordjman, Moshe, Lee, Youngtack, Vardi, Alon, Kalish, Rafi, and del Alamo, Jesus A.

Abstract

High electron affinity transition-metal oxides (TMOs) have gained a central role in two-dimensional (2D) electronics by enabling unprecedented surface charge doping efficiency in numerous exotic 2D solid-state semiconductors. Among them, diamond-based 2D electronics are entering a new era by using TMOs as surface acceptors instead of previous molecular-like unstable acceptors. Similarly, surface-doped diamond with TMOs has recently yielded record sheet hole concentrations (2 × 1014 cm−2) and launched the quest for its implementation in microelectronic devices. Regrettably, field-effect transistor operation based on this surface doping has been so far disappointing due to fundamental material obstacles such as (i) carrier scattering induced by nonhomogeneous morphology of TMO surface acceptor layer, (ii) stoichiometry changes caused by typical transistor fabrication process, and (iii) carrier transport loss due to electronic band energy misalignment. This work proposes and demonstrates a general strategy that synergistically surmounts these three barriers by developing an atomic layer deposition of a hydrogenated MoO3 layer as a novel efficient surface charge acceptor for transistors. It shows high surface uniformity, enhanced immunity to harsh fabrication conditions, and benefits from tunable electronic gap states for improving carrier transfer at interfaces. These breakthroughs permit crucial integration of TMO surface doping into transistor fabrication flows and allow outperforming electronic devices to be reached.

Published
2018

43. A Diamond: H/WO3 Metal-Oxide-Semiconductor Field-Effect Transistor

Author

Yin, Zongyou, Tordjman, Moshe, Alon, Vardi, Kalish, Rafi, del Alamo, Jesus A., Yin, Zongyou, Tordjman, Moshe, Alon, Vardi, Kalish, Rafi, and del Alamo, Jesus A.

Abstract

A p-type Diamond:H/WO 3 metal-oxide-semiconductor field-effect transistor (MOSFET) based on surface transfer doping is demonstrated. Using a low-temperature ALD-grown HfO 2 as gate insulator, the Diamond:H/WO 3 MOSFETs show excellent output characteristics, gate-controllable 2-D hole gas, and low gate leakage current. Long-channel FETs exhibit improved subthreshold behavior but reduced transconductance with respect to short-channel devices. An observed WO 3 -thickness-dependent threshold voltage is consistent with enhanced surface transfer doping as the WO 3 layer is thinned down. Low-temperature measurements suggest a significantly lower mobility than expected in this material system. This illustrates the challenge of maintaining high TMO quality during device fabrication.

Published
2018

44. An insulator-lined silicon substrate-via technology with high aspect ratio

Author

Wu, Joyce H., Scholvin, Jorg, and Del Alamo, Jesus A.

Subjects
Integrated circuits -- Research, Semiconductors -- Research, Business, Electronics, Electronics and electrical industries
Abstract

A new high-aspect ration substrate-via technology in silicon, with a SiN insulator liner, is reported. The via is filled with electroplated Cu.

Published
2001

46. A new drain-current injection technique for the measurement of off-state breakdown voltage in FET's

Author

Bahl, Sandeep R. and del Alamo, Jesus A.

Subjects
Field-effect transistors -- Analysis, Breakdown (Electricity) -- Influence, Business, Electronics, Electronics and electrical industries
Abstract

The off-state breakdown voltage of field effect transistors (FET) is measured by an elementary three-terminal technique. The current is fed into the drain of the on-state device when there is grounding of the sources, and the device is closed by ramping down the gate. This procedure results in a steep rise and subsequent fall in the drain source voltage. The rise in voltage yields a definition of three-terminal breakdown voltage.

Published
1993

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