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1. Hafnia-based Phase-Change Ferroelectric Steep-Switching FETs on a 2-D MoS$_2$ platform

Author

Sanjay, Sooraj, A, Jalaja M., Bhat, Navakanta, and Nukala, Pavan

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

Ferroelectric field-effect transistors integrated on 2D semiconducting platforms are extremely relevant for low power electronics. Here, we propose and demonstrate a novel phase-change ferroelectric field effect transistor (PCFE-FET) for steep switching applications. Our gate stack is engineered as a ferroelectric Lanthanum doped hafnium oxide (LHO) proximity coupled with Mott insulator Ti$_x$O$_{2x-1}$(N$_y$) and is integrated onto a 2D MoS$_2$ channel. The interplay of partial polarization switching in the ferroelectric LHO layer and reversible field-tunable metal-insulator transition (MIT) in Ti$_x$O$_{2x-1}$(N$_y$) layer concomitantly triggers polar to non-polar phase transition in the LHO layer between 200 and 220 K. This results in distinctive step-like features in the channel current during DC measurements, and random current fluctuations in high-speed measurements with slim anticlockwise hysteresis. Our devices show subthreshold slopes as steep as 25 mV/dec at 210 K, breaking the Boltzmann limit. Our gate stack is also potentially tunable for operation at temperatures of interest, presenting innovative gate stack engineering approaches for low-power computing solutions.

Published
2024

3. Large electro-opto-mechanical coupling in VO2 neuristors

Author

Khandelwal, Upanya, Sandilya, Rama Satya, Rai, Rajeev Kumar, Sharma, Deepak, Mahapatra, Smruti Rekha, Mondal, Debasish, Bhat, Navakanta, Aetkuri, Naga Phani, Avasthi, Sushobhan, Chandorkar, Saurabh, and Nukala, Pavan

Subjects
Physics - Applied Physics
Abstract

Biological neurons are electro-mechanical systems, where the generation and propagation of an action potential is coupled to generation and transmission of an acoustic wave. Neuristors, such as VO2, characterized by insulator-metal transition (IMT) and negative differential resistance, can be engineered as self-oscillators, which are good approximations of biological neurons in the domain of electrical signals. In this study, we show that these self-oscillators are coupled electro-opto-mechanical systems, with better energy conversion coefficients than the conventional electromechanical or electrooptical materials. This is due to the significant contrast in the material's resistance, optical refractive index and density across the induced temperature range in a Joule heating driven IMT. We carried out laser interferometry to measure the opto-mechanical response while simultaneously driving the devices electrically into self-oscillations of different kinds. We analyzed films of various thicknesses, engineered device geometry and performed analytical modelling to decouple the effects of refractive index change vis-a-vis mechanical strain in the interferometry signal. We show that the effective piezoelectric coefficient (d13*) for our neuristor devices is 660 pm/V, making them viable alternatives to Pb-based piezoelectrics for MEMS applications. Furthermore, we show that the effective electro-optic coefficient (r13*) is ~22 nm/V, which is much larger than that in thin-film and bulk Pockels materials., Comment: 37 pages, 20 Figures

Published
2023

4. Self-assembled neuromorphic networks at self-organized criticality in Ag-hBN platform

Author

Rao, Ankit, Sanjay, Sooraj, Ahmadi, Majid, Venugopalrao, Anirudh, Bhat, Navakanta, Kooi, Bart, Raghavan, Srinivasan, and Nukala, Pavan

Subjects
Quantitative Biology - Neurons and Cognition, Condensed Matter - Disordered Systems and Neural Networks, Computer Science - Emerging Technologies
Abstract

Networks and systems which exhibit brain-like behavior can analyze information from intrinsically noisy and unstructured data with very low power consumption. Such characteristics arise due to the critical nature and complex interconnectivity of the brain and its neuronal network. We demonstrate that a system comprising of multilayer hexagonal Boron Nitride (hBN) films contacted with Silver (Ag), that can uniquely host two different self-assembled networks, which are self-organized at criticality (SOC). This system shows bipolar resistive switching between high resistance (HRS) and low resistance states (LRS). In the HRS, Ag clusters (nodes) intercalate in the van der Waals gaps of hBN forming a network of tunnel junctions, whereas the LRS contains a network of Ag filaments. The temporal avalanche dynamics in both these states exhibit power-law scaling, long-range temporal correlation, and SOC. These networks can be tuned from one to another with voltage as a control parameter. For the first time, different neuron-like networks are realized in a single CMOS compatible, 2D materials platform.

Published
2022

6. Thickness Dependent Parasitic Channel Formation at AlN/Si Interfaces

Author

Chandrasekar, Hareesh, Bhat, K N, Rangarajan, Muralidharan, Raghavan, Srinivasan, and Bhat, Navakanta

Subjects
Condensed Matter - Materials Science
Abstract

The performance of GaN-on-Silicon electronic devices is severely degraded by the presence of a parasitic conduction pathway at the nitride-substrate interface which contributes to switching losses and lower breakdown voltages. The physical nature of such a parasitic channel and its properties are however, not well understood. We report on a pronounced thickness dependence of the parasitic channel formation at AlN/Si interfaces due to increased surface acceptor densities at the interface in silicon. The origin of these surface acceptors is analyzed using secondary ion mass spectroscopy measurements and traced to thermal acceptor formation due to Si-O-N complexes. Low-temperature (5K) magneto-resistance (MR) data reveals a transition from positive to negative MR with increasing AlN film thickness indicating the presence of an inversion layer of electrons which also contributes to parasitic channel formation but whose contribution is secondary at room temperatures., Comment: 23 pages, 7 figures

Published
2017
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7. An Early In-Situ Stress Signature of the AlN-Si Pre-growth Interface for Successful Integration of Nitrides with (111) Si

Author

Chandrasekar, Hareesh, Mohan, Nagaboopathy, Bardhan, Abheek, Bhat, KN, Bhat, Navakanta, Ravishankar, N, and Raghavan, Srinivasan

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

The integration of MOCVD grown group III-A nitride device stacks on Si (111) substrates is critically dependent on the quality of the first AlN buffer layer grown. A Si surface that is both oxide-free and smooth is a primary requirement for nucleating such layers. A single parameter, the AlN layer growth stress, is shown to be an early (within 50 nm), clear (<0.5 GPa versus >1 GPa) and fail-safe indicator of the pre-growth surface, and the AlN quality required for successful epitaxy. Grain coalescence model for stress generation is used to correlate growth stress, the AlN-Si interface and crystal quality., Comment: 18 pages, 6 figures

Published
2017
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8. Dielectric Engineering of HfO2 Gate Stacks Towards Normally-ON and Normally-OFF GaN HEMTs on Silicon

Author

Chandrasekar, Hareesh, Kumar, Sandeep, Ganapathi, K. L., Prabhu, Shreesha, Dolmanan, Surani Bin, Tripathy, Sudhiranjan, Raghavan, Srinivasan, Bhat, K. N., Mohan, Sangeneni, Muralidharan, R., Bhat, Navakanta, and Nath, Digbijoy N.

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

We report on the interfacial electronic properties of HfO2 gate dielectrics both, with GaN towards normally-OFF recessed HEMT architectures and the AlGaN barrier for normally-ON AlGaN/GaN MISHEMTs for GaN device platforms on Si. A conduction band offset of 1.9 eV is extracted for HfO2/GaN along with a very low density of fixed bulk and interfacial charges. Conductance measurements on HfO2/GaN MOSCAPs reveal an interface trap state continuum with a density of 9.37x1012 eV-1cm-2 centered at 0.48 eV below EC. The forward and reverse current densities are shown to be governed by Fowler-Nordheim tunneling and Poole-Frenkel emission respectively. Normally-ON HfO2/AlGaN/GaN MISHEMTs exhibit negligible shifts in threshold voltage, transconductances of 110mS/mm for 3 {\mu}m gate length devices, and three-terminal OFF-state gate leakage currents of 20 nA/mm at a VD of 100 V. Dynamic capacitance dispersion measurements show two peaks at the AlGaN/GaN interface corresponding to slow and fast interface traps with a peak Dit of 5.5x1013 eV-1cm-2 and 1.5x1013 eV-1cm-2 at trap levels 0.55 eV and 0.46 eV below EC respectively. The HfO2/AlGaN interface exhibits a peak Dit of 4.4x1013 eV-1cm- 2 at 0.45 eV below EC., Comment: 6 pages, 10 figures

Published
2017

9. Truncated Albumins as Novel Surrogate Biomarkers in Diabetes Therapy: Epiphenomena and Potential Clinical Applications.

Author

Vaishnav, Madhumati S., Kumari, Namita, Srikanta, Sathyanarayana, Simha, Vinaya, Krishnaswamy, Patnam R., and Bhat, Navakanta

Abstract

Aims/Hypothesis: Among various albumin posttranslational modifications (PTMs), N- and C-terminal truncations (HSA-DA and HSA-L) have also shown biomarker potential in disease states. We examined albumin truncation longitudinal trends and correlations during diabetes therapy toward possible future clinical applications. Methods: In a preliminary longitudinal therapy investigation, mass spectrometry was employed to track PTMs of human serum albumin (HSA), including glycation (GA), cysteinylation (CA or HNA1; reversible), di/trioxidation (OA or HNA2; irreversible), and truncation (TA). These modifications were correlated with ongoing therapy in four distinct subject groups: type 1 diabetes (T1DM), type 2 diabetes (T2DM), prediabetes-obesity (PDOB), and healthy controls (NORM), observed over a follow-up period extending up to 280 days. Results: Diabetes was associated with significant reduction ("deficiency") of measured albumin truncations (For HSA-DA: T2DM = 0.32 ± 0.3%, p = 2E-08; T1DM = 1.02 ± 0.4%, p = 3E-05; PDOB = 1.61 ± 0.2%, p = 0.004; compared to NORM = 2.08 ± 0.2%). Albumin truncation reduction was more striking in T2DM (HSA-DA: T2DM vs. T1DM: p = 0.004). Improvements in glycemic control and decrease of albumin glycation during diabetes therapy were associated with concomitant increase of albumin truncations toward the "healthy" normal ranges, and vice versa ("mirror image" trends). Accordingly, albumin truncation correlated inversely with albumin glycation (HSA-DA vs. GA: R = −0.53, p = 1E-09). Conclusions: The "epiphenomenon" of albumin truncation (reflecting the severity of mean hyperglycemia and also insulin resistance) can possibly provide novel, sensitive, and complementary biomarkers (e.g., via simpler HSA-DA peptide fragment immunoassays) to monitor efficacy of diabetes therapy and also progression from "healthy" to prediabetes and type 2 diabetes, highlighting potential diagnostic and prognostic utility in clinical diabetes care. [ABSTRACT FROM AUTHOR]

Published
2024
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12. Photoresponse of atomically thin MoS2 layers and their planar heterojunctions

Author

Kallatt, Sangeeth, Umesh, Govindarao, Bhat, Navakanta, and Majumdar, Kausik

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

MoS2 monolayers exhibit excellent light absorption and large thermoelectric power, which are, however, accompanied with very strong exciton binding energy - resulting in complex photoresponse characteristics. We study the electrical response to scanning photo-excitation on MoS2 monolayer (1L) and bilayer (2L) devices, and also on monolayer/bilayer (1L/2L) planar heterojunction and monolayer/few-layer/multi-layer (1L/FL/ML) planar double heterojunction devices to unveil the intrinsic mechanisms responsible for photocurrent generation in these materials and junctions. Strong photoresponse modulation is obtained by scanning the position of the laser spot, as a consequence of controlling the relative dominance of a number of layer dependent properties, including (i) photoelectric effect (PE), (ii) photothermoelectric effect (PTE), (iii) excitonic effect, (iv) hot photo-electron injection from metal, and (v) carrier recombination. The monolayer and bilayer devices show peak photoresponse when the laser is focused at the source junction, while the peak position shifts to the monolayer/multi-layer junction in the heterostructure devices. The photoresponse is found to be dependent on the incoming light polarization when the source junction is illuminated, although the polarization sensitivity drastically reduces at the monolayer/multi-layer heterojunction. Finally, we investigate laser position dependent transient response of photocurrent to reveal trapping of carriers in SiO2 at the source junction is the critical factor to determine the transient response in 2D photodetectors, and also show that, by systematic device design, such trapping can be avoided in the heterojunction devices, resulting in fast transient response. The insights obtained will play an important role in designing fast 2D TMDs based photodetector and related optoelectronic and thermoelectric devices., Comment: Nanoscale, 2016

Published
2016
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16. Anion-Exchange-Mediated Synthesis of Hollow 2D Layered Materials and Heterostructures: Mechanism and Room-Temperature Gas-Sensing Properties

Author

Rai, Rajeev Kumar, Goyal, Naveen, Sharma, Deepak, Ram, Ranit, Jagadish, Koushik, Bhat, Navakanta, and Ravishankar, Narayanan

Abstract

The design of nanostructures with unique morphologies and enhanced functionalities is a cornerstone of modern materials science. Ion exchange reactions in inorganic crystals offer a versatile approach for precisely controlling the composition, morphology, and properties of the materials through stepwise transformations. In this study, we report the anion-exchange-mediated conversion of 2D layered material SnS2into SnSe2, with SnS2–SnSe2lateral heterostructures as intermediates. This transformation, driven by the disparate diffusion rates of S2–and Se2–ions, leads to the generation of hexagonal nanorings of SnSe2(inaccessible by direct synthetic routes) via the Kirkendall effect. By carefully balancing the diffusion kinetics through concentration control, we successfully synthesized continuous SnSe2nanosheets. To elucidate the anion-exchange mechanism, we conducted a comprehensive investigation using electron microscopy techniques, varying parameters such as time, precursor concentration, and reagents. Our findings revealed that the exchange process initiates at the edges of the template SnS2nanosheets and progresses inward. Cross-sectional atomic-resolution electron microscopy of the interfaces and layer stacking in the SnS2–SnSe2heterostructure uncovered numerous defects attributed to ion migration and lattice mismatch, which were not detectable in planar views. Furthermore, as-synthesized materials are explored for gas-sensing applications. Our anion-exchange-derived SnS2–SnSe2heterostructure and SnSe2exhibited exceptional selectivity and sensitivity toward NO2gas (response >700%) at room temperature comparable to state-of-art sensors, significantly outperforming the pristine SnS2material, which required elevated temperatures (150 °C) for optimal response. This study underscores the potential of anion exchange as a powerful tool for designing novel nanomaterials with tailored properties and applications, particularly in the realm of gas sensing.

Published
2025
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18. Surface States Engineering of Metal/MoS2 Contacts Using Sulfur Treatment for Reduced Contact Resistance and Variability

Author

Bhattacharjee, Shubhadeep, Ganapathi, Kolla Lakshmi, Nath, Digbijoy N., and Bhat, Navakanta

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Variability and lack of control in the nature of contacts between metal/MoS2 interface is a major bottleneck in the realisation of high-performance devices based on layered materials for several applications. In this letter, we report on the reduction in Schottky barrier height at metal/MoS2 interface by engineering the surface states through sulphur treatment. Electrical characteristics for back-gated MoS2 field effect transistor structures were investigated for two high work-function metal contacts Ni and Pd. Contacts on MoS2 treated with sulphur exhibited significant improvements in Ohmic nature with concomitant reduction in variability compared to those on untreated MoS2 films leading to a 2x increase in extracted mobility. X-ray Photoelectron Spectroscopy (XPS) measurements, Raman Spectroscopy and comparison of threshold voltages indicated absence of additional doping or structural changes due to sulphur treatment. The Schottky barrier heights were extracted from temperature-dependent transfer characteristics based on the thermionic current model. A reduction in barrier height of 80 and 135 meV extracted for Ni/MoS2 and Pd/MoS2 contacts respectively is hence attributed to the increase in surface states (or stronger Fermi level pinning) due to sulphur treatment. The corresponding charge neutrality levels at metal/MoS2 interface, were extracted to be 0.16 eV (0.17 eV) below the conduction band before (after) Sulphur treatment. This first report of surface states engineering in MoS2 leading to superior contacts is expected to significantly benefit the entire class of devices based on layered 2D materials., Comment: 13 pages, 5 figures

Published
2015
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19. Optical Phonon Limited High Field Transport in Layered Materials

Author

Chandrasekar, Hareesh, Ganapathi, Kolla L., Bhattacharjee, Shubhadeep, Bhat, Navakanta, and Nath, Digbijoy N.

Subjects
Condensed Matter - Materials Science
Abstract

An optical phonon limited velocity model has been employed to investigate high-field transport in a selection of layered 2D materials for both, low-power logic switches with scaled supply voltages, and high-power, high-frequency transistors. Drain currents, effective electron velocities and intrinsic cut-off frequencies as a function of carrier density have been predicted thus providing a benchmark for the optical phonon limited high-field performance limits of these materials. The optical phonon limited carrier velocities of a selection of transition metal dichalcogenides and black phosphorus are found to be modest as compared to their n-channel silicon counterparts, questioning the utility of these devices in the source-injection dominated regime. h-BN, at the other end of the spectrum, is shown to be a very promising material for high-frequency high-power devices, subject to experimental realization of high carrier densities, primarily due to its large optical phonon energy. Experimentally extracted saturation velocities from few-layer MoS2 devices show reasonable qualitative and quantitative agreement with predicted values. Temperature dependence of measured vsat is discussed and found to fit a velocity saturation model with a single material dependent fit parameter., Comment: 8 pages, 6 figures

Published
2015
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20. Estimation of background carrier concentration in fully depleted GaN films

Author

Chandrasekar, Hareesh, Singh, Manikant, Raghavan, Srinivasan, and Bhat, Navakanta

Subjects
Condensed Matter - Materials Science
Abstract

Buffer leakage is an important parasitic loss mechanism in AlGaN/GaN HEMTs and hence various methods are employed to grow semi-insulating buffer layers. Quantification of carrier concentration in such buffers using conventional capacitance based profiling techniques is challenging due to their fully depleted nature even at zero bias voltages. We provide a simple and effective model to extract carrier concentrations in fully depleted GaN films using capacitance-voltage (C-V) measurements. Extensive mercury probe C-V profiling has been performed on GaN films of differing thicknesses and doping levels in order to validate this model. Carrier concentrations as extracted from both the conventional C-V technique for partially depleted films having the same doping concentration, and Hall measurements show excellent agreement with those predicted by the proposed model thus establishing the utility of this technique. This model can be readily extended to estimate background carrier concentrations from the depletion region capacitances of HEMT structures and fully depleted films of any class of semiconductor materials., Comment: 16 pages, 6 figures

Published
2015
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21. Growth Stress Induced Tunability of Dielectric Constant in Thin Films

Author

Narayanachari, K. V. L. V., Chandrasekar, Hareesh, Banerjee, Amiya, Varma, K. B. R., Ranjan, Rajeev, Bhat, Navakanta, and Raghavan, Srinivasan

Subjects
Condensed Matter - Materials Science
Abstract

It is demonstrated here that growth stress has a substantial effect on the dielectric constant of zirconia thin films. The correct combination of parameters - phase, texture and stress - is shown to yield films with high dielectric constant and best reported equivalent oxide thickness of 0.8 nm. The stress effect on dielectric constant is twofold, firstly, by the effect on phase transitions and secondly by the effect on interatomic distances. We discuss and explain the physical mechanisms involved in the interplay between the stress, phase changes and the dielectric constant in detail., Comment: 11 pages, 5 figures

Published
2015
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22. Spotting 2-D Atomic Layers on Aluminum Nitride Thin Films

Author

Chandrasekar, Hareesh, B, Krishna Bharadwaj, Vaidyuala, Kranthi Kumar, Suran, Swathi, Bhat, Navakanta, Varma, Manoj, and Raghavan, Srinivasan

Subjects
Condensed Matter - Materials Science
Abstract

The availability of large-area substrates imposes an important constraint on the technological and commercial realization of devices made of layered materials. Aluminum nitride films on silicon are shown to be promising candidate materials as large-area substrates for such devices. Herein, the optical contrast of exemplar 2D layers - MoS2and graphene - on AlN films has been investigated as a necessary first step to realize devices on these substrates. Significant contrast enhancements are predicted and observed on AlN films compared to conventional SiO2films. Quantitative estimates of experimental contrast using reflectance spectroscopy show very good agreement with predicted values., Comment: 17 pages, 8 figures, supplementary information

Published
2015
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24. Large electro-opto-mechanical coupling in VO2 neuristors

Author

Khandelwal, Upanya, primary, Sandilya, Rama Satya, additional, Rai, Rajeev Kumar, additional, Sharma, Deepak, additional, Mahapatra, Smruti Rekha, additional, Mondal, Debasish, additional, Bhat, Navakanta, additional, Aetkuri, Naga Phani, additional, Avasthi, Sushobhan, additional, Chandorkar, Saurabh, additional, and Nukala, Pavan, additional

Published
2024
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33. Optimization of a Ferrocene Carboxylic Acid-Based Enzymatic Glucose Sensor for Continuous Glucose Monitoring

Author

Nayak, Kavya K. and Bhat, Navakanta

Abstract

Continuous glucose monitoring (CGM) systems are indispensable for managing diabetes, providing real-time glucose trends for effective therapeutic decision-making. The present work focuses on designing and developing an enzymatic electrochemical sensor with a three-electrode configuration for CGM applications. We designed, fabricated, and tested the metal electrodes on silicon/silicon oxide (Si/SiO2) as well as polyethylene terephthalate (PET) substrates. The sensor performance is optimized with respect to variables, such as area of electrodes, type of electrodes, and enzyme-mediator ratio for continuous glucose detection. A flow setup is also developed for in vitro testing by a controlled supply of glucose. The fabricated sensor exhibits a detection range of 50–400 mg/dL and a sensitivity of 34 nA/mgdL $^{-{1}}$ /mm2 at an operating potential of 0.35 V with minimal susceptibility to common interference molecules. The continuous glucose measurements in vitro show a retention of 88% of the sensor’s initial response after seven days of operation. The simplified microfabrication process combined with the use of stable, readily available mediator molecule and a simple immobilization technique, eliminating the need for elaborate synthesis procedures, offers a scalable and cost-effective approach to develop an indigenous CGM system.

Published
2024
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34. Underlap Optimization in HFinFET in Presence of Interface Traps

Author

Majumdar, Kausik, Konjady, Rajaram S., S., Raj Tejas, and Bhat, Navakanta

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In this work, using 3D device simulation, we perform an extensive gate to source/drain underlap optimization for the recently proposed hybrid transistor, HFinFET, to show that the underlap lengths can be suitably tuned to improve the on-off ratio as well as the subthreshold characteristics in an ultra-short channel n-type device without significant on performance degradation. We also show that the underlap knob can be tuned to mitigate the device quality degradation in presence of interface traps. The obtained results are shown to be very promising when compared against ITRS 2009 performance projections as well as published state of the art planar and non-planar Silicon MOSFET data of comparable gate lengths using standard benchmarking techniques., Comment: 5 pages, 8 figures; Accepted in IEEE Transactions on Nanotechnology

Published
2011
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35. High On-Off Ratio Bilayer Graphene Complementary Field Effect Transistors

Author

Majumdar, Kausik, Murali, Kota V. R. M., Bhat, Navakanta, Xia, Fengnian, and Lin, Yu-Ming

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In this paper, we propose a novel S/D engineering for dual-gated Bilayer Graphene (BLG) Field Effect Transistor (FET) using doped semiconductors (with a bandgap) as source and drain to obtain unipolar complementary transistors. To simulate the device, a self-consistent Non-Equilibrium Green's Function (NEGF) solver has been developed and validated against published experimental data. Using the simulator, we predict an on-off ratio in excess of $10^4$ and a subthreshold slope of ~110mV/decade with excellent scalability and current saturation, for a 20nm gate length unipolar BLG FET. However, the performance of the proposed device is found to be strongly dependent on the S/D series resistance effect. The obtained results show significant improvements over existing reports, marking an important step towards bilayer graphene logic devices., Comment: 4 pages, 11 figures

Published
2011
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36. External Bias Dependent Direct To Indirect Bandgap Transition in Graphene Nanoribbon

Author

Majumdar, Kausik, Murali, Kota V. R. M., Bhat, Navakanta, and Lin, Yu-Ming

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

In this work, using self-consistent tight-binding calculations, for the first time, we show that a direct to indirect bandgap transition is possible in an armchair graphene nanoribbon by the application of an external bias along the width of the ribbon, opening up the possibility of new device applications. With the help of Dirac equation, we qualitatively explain this bandgap transition using the asymmetry in the spatial distribution of the perturbation potential produced inside the nanoribbon by the external bias. This is followed by the verification of the bandgap trends with a numerical technique using Magnus expansion of matrix exponentials. Finally, we show that the carrier effective masses possess tunable sharp characters in the vicinity of the bandgap transition points., Comment: Accepted for publication in Nano Letters

Published
2010
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37. Effects of Parasitics and Interface Traps On Ballistic Nanowire FET In The Ultimate Quantum Capacitance Limit

Author

Majumdar, Kausik, Bhat, Navakanta, Majhi, Prashant, and Jammy, Raj

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In this paper, we focus on the performance of a nanowire Field Effect Transistor (FET) in the Ultimate Quantum Capacitance Limit (UQCL) (where only one subband is occupied) in the presence of interface traps ($D_{it}$), parasitic capacitance ($C_L$) and source/drain series resistance ($R_{s,d}$) using a ballistic transport model and compare the performance with its Classical Capacitance Limit (CCL) counterpart. We discuss four different aspects relevant to the present scenario, namely, (i) gate voltage dependent capacitance, (ii) saturation of the drain current, (iii) the subthreshold slope and (iv) the scaling performance. To gain physical insights into these effects, we also develop a set of semi-analytical equations. The key observations are: (1) A strongly energy-quantized nanowire shows non-monotonic multiple peak C-V characteristics due to discrete contributions from individual subbands; (2) The ballistic drain current saturates better in the UQCL compared to CCL, both in presence and absence of $D_{it}$ and $R_{s,d}$; (3) The subthreshold slope does not suffer any relative degradation in the UQCL compared to CCL, even with $D_{it}$ and $R_{s,d}$; (4) UQCL scaling outperforms CCL in the ideal condition; (5) UQCL scaling is more immune to $R_{s,d}$, but presence of $D_{it}$ and $C_L$ significantly degrades scaling advantages in the UQCL., Comment: Accepted at IEEE Transactions on Electron Devices

Published
2010
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38. HFinFET: A Scalable, High Performance, Low Leakage Hybrid N-Channel FET

Author

Majumdar, Kausik, Majhi, Prashant, Bhat, Navakanta, and Jammy, Raj

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In this letter we propose the design and simulation study of a novel transistor, called HFinFET, which is a hybrid of a HEMT and a FinFET, to obtain excellent performance and good off state control. Followed by the description of the design, 3D device simulation has been performed to predict the characteristics of the device. The device has been benchmarked against published state of the art HEMT as well as planar and non-planar Si NMOSFET data of comparable gate length using standard benchmarking techniques., Comment: 3 pages, 4 figures

Published
2010
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39. Bandstructure Effects in Ultra-Thin-Body DGFET: A Fullband Analysis

Author

Majumdar, Kausik and Bhat, Navakanta

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

This paper discusses a few unique effects of ultra-thin-body double-gate NMOSFET that are arising from the bandstructure of the thin film Si channel. The bandstructure has been calculated using 10-orbital $sp^3d^5s^*$ tight-binding method. A number of intrinsic properties including band gap, density of states, intrinsic carrier concentration and parabolic effective mass have been derived from the calculated bandstructure. The spatial distributions of intrinsic carrier concentration and $<100>$ effective mass, arising from the wavefunction of different contributing subbands are analyzed. A self-consistent solution of Poisson-Schrodinger coupled equation is obtained taking the full bandstructure into account, which is then applied to an insightful analysis of volume inversion. The spatial distribution of carriers over the channel of a DGFET has been calculated and its effects on effective mass and channel capacitance are discussed., Comment: 13 pages, 21 figures

Published
2010
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40. Intrinsic Limits of Subthreshold Slope in Biased Bilayer Graphene Transistor

Author

Majumdar, Kausik, Murali, Kota V. R. M., Bhat, Navakanta, and Lin, Yu-Ming

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In this work, we investigate the intrinsic limits of subthreshold slope in a dual gated bilayer graphene transistor using a coupled self-consistent Poisson-bandstructure solver. We benchmark the solver by matching the bias dependent bandgap results obtained from the solver against published experimental data. We show that the intrinsic bias dependence of the electronic structure and the self-consistent electrostatics limit the subthreshold slope obtained in such a transistor well above the Boltzmann limit of 60mV/decade at room temperature, but much below the results experimentally shown till date, indicating room for technological improvement of bilayer graphene., Comment: 10 pages, 2 figures

Published
2010
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43. Albumin Oxidation and Albumin Glycation Discordance During Type 2 Diabetes Therapy: Biological and Clinical Implications.

Author

Vaishnav, Madhumati S., Kumari, Namita, Srikanta, Sathyanarayana, Simha, Vinaya, Krishnaswamy, Patnam R., Balaram, Padmanabhan, and Bhat, Navakanta

Abstract

Aims: Cys34 albumin redox modifications (reversible "cysteinylation" and irreversible "di/trioxidation"), besides being just oxidative stress biomarkers, may have primary pathogenetic roles to initiate and/or aggravate cell, tissue, and vascular damage in diabetes. In an exploratory "proof-of-concept" pilot study, we examined longitudinal changes in albumin oxidation during diabetes therapy. Methods: Mass spectrometric analysis was utilized to monitor changes in human serum albumin (HSA) post-translational modifications {glycation [glycated albumin (GA)], cysteinylation [cysteinylated albumin (CA) or human non-mercaptalbumin-1; reversible], di/trioxidation (di/trioxidized albumin or human non-mercaptalbumin-2; irreversible), and truncation (truncated albumin)} during ongoing therapy. Four informative groups of subjects were evaluated [type 1 diabetes (T1DM), type 2 diabetes (T2DM), prediabetes-obesity, and healthy controls] at baseline, and subjects with diabetes were followed for a period up to 280 days. Results: At baseline, T2DM was associated with relatively enhanced albumin cysteinylation (CA% total) compared with T1DM (P = 0.004), despite comparable mean hyperglycemia (P values: hemoglobin A1c = 0.09; GA = 0.09). T2DM, compared with T1DM, exhibited selectively and significantly higher elevations of all the "individual" glycated cum cysteinylated ("multimodified") albumin isoforms (P values: CysHSA+1G = 0.003; CysHSA+2G = 0.007; and CysHSA+3G = 0.001). Improvements in glycemic control and decreases in albumin glycation during diabetes therapy in T2DM were not always associated with concurrent reductions of albumin cysteinylation, and in some therapeutic situations, albumin cysteinylation worsened (glycation–cysteinylation discordance). Important differences were observed between the effects of sulfonylureas and metformin on albumin molecular modifications. Conclusions: T2DM was associated with higher oxidative (cysteinylation) and combined (cysteinylation plus glycation) albumin molecular modifications, which are not ameliorated by improved glucose control alone. Further studies are required to establish the clinical significance and optimal therapeutic strategies to address oxidative protein damage and resulting consequences in diabetes. [ABSTRACT FROM AUTHOR]

Published
2024
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44. Large electro-opto-mechanical coupling in VO2 neuristors.

Author

Khandelwal, Upanya, Sandilya, Rama Satya, Rai, Rajeev Kumar, Sharma, Deepak, Mahapatra, Smruti Rekha, Mondal, Debasish, Bhat, Navakanta, Aetkuri, Naga Phani, Avasthi, Sushobhan, Chandorkar, Saurabh, and Nukala, Pavan

Subjects
STRAINS & stresses (Mechanics), TRANSMISSION of sound, METAL-insulator transitions, LASER interferometry, ACTION potentials, REFRACTIVE index
Abstract

Biological neurons are electro-mechanical systems, where the generation and propagation of an action potential are coupled to the generation and transmission of an acoustic wave. Neuristors, such as VO2, characterized by insulator-metal transition (IMT) and negative differential resistance, can be engineered as self-oscillators, which are good approximations of biological neurons in the domain of electrical signals. In this study, we show that these self-oscillators are coupled electro-opto-mechanical systems, with better energy conversion coefficients than the conventional electro-mechanical or electro-optical materials. This is due to the significant contrast in the material's resistance, optical refractive index, and density across the induced temperature range in a Joule heating driven IMT. We carried out laser interferometry to measure the opto-mechanical response while simultaneously driving the devices electrically into self-oscillations of different kinds. We analyzed films of various thicknesses, engineered device geometry, and performed analytical modeling to decouple the effects of refractive index change vis-à-vis mechanical strain in the interferometry signal. We show that the effective piezoelectric coefficient (d13*) for our neuristor devices is 660 ± 20 pm/V, with a 31% internal energy conversion efficiency, making them viable alternatives to Pb-based piezoelectrics for MEMS applications. Furthermore, we show that the effective electro-optic coefficient (r13*) is ∼22 nm/V, which is much larger than that in thin-film and bulk Pockels materials. [ABSTRACT FROM AUTHOR]

Published
2024
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46. Application of a Nanotechnology-Based, Point-of-Care Diagnostic Device in Diabetic Kidney Disease

Author

Kumar, Vinay, Hebbar, Suraj, Bhat, Ananthram, Panwar, Sachin, Vaishnav, Madhumati, Muniraj, Kavitha, Nath, Vasanthi, Vijay, Reshma Banaki, Manjunath, Sapna, Thyagaraj, Babithadevi, Siddalingappa, Chandraprabha, Chikkamoga Siddaiah, Muralidharakrishna, Dasgupta, Indranil, Anandh, Urmila, Kamala, Thummala, Srikanta, S.S., Krishnaswamy, P.R., and Bhat, Navakanta

Published
2018
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