Temperature Dependence of the Transport Properties of InN

Similar documents
Advanced Semiconductor Device Simulation at TU Wien

Research Article Electron Transport Characteristics of Wurtzite GaN

32. Electron Transport Within III-V Semiconductors

Steady-State and Transient Electron Transport Within the III V Nitride Semiconductors, GaN, AlN, and InN: A Review

Monte Carlo Based Calculation of Electron Transport Properties in Bulk InAs, AlAs and InAlAs

An energy relaxation time model for device simulation

MONTE CARLO SIMULATION OF THE ELECTRON MOBILITY IN STRAINED SILICON

NUMERICAL CALCULATION OF THE ELECTRON MOBILITY IN GaAs SEMICONDUCTOR UNDER WEAK ELECTRIC FIELD APPLICATION

Reliability Concerns due to Self-Heating Effects in GaN HEMTs

CHARACTERIZATION, MODELING, AND SIMULATION OF In 0.12 Al 0.88 N/GaN HEMTs

M R S Internet Journal of Nitride Semiconductor Research

Comparison of electron transport properties in submicrometer InAs, InP and GaAs n + -i-n + diode using ensemble Monte Carlo simulation

A Zero Field Monte Carlo Algorithm Accounting for the Pauli Exclusion Principle

A -SiC MOSFET Monte Carlo Simulator Including

ELECTRONS AND PHONONS IN SEMICONDUCTOR MULTILAYERS

POTENTIAL PERFORMANCE OF SiC AND GaN BASED METAL SEMICONDUCTOR FIELD EFFECT TRANSISTORS

Device and Monte Carlo Simulation of GaN material and devices. Presenter: Ziyang Xiao Advisor: Prof. Neil Goldsman University of Maryland

A transient electron transport analysis of bulk wurtzite zinc oxide

drift vel. [10 cm/s] electric field [kv/cm] drift vel. [10 cm/s] electric field [kv/cm] T = 300 K GaN GaAs AlN

Review of Semiconductor Physics. Lecture 3 4 Dr. Tayab Din Memon

Quantum Phenomena & Nanotechnology (4B5)

Electrical Transport. Ref. Ihn Ch. 10 YC, Ch 5; BW, Chs 4 & 8

Electro-Thermal Transport in Silicon and Carbon Nanotube Devices E. Pop, D. Mann, J. Rowlette, K. Goodson and H. Dai

Spin Lifetime Enhancement by Shear Strain in Thin Silicon-on-Insulator Films. Dmitry Osintsev, Viktor Sverdlov, and Siegfried Selberherr

CALCULATION OF ELECRON MOBILITY IN WZ-AlN AND AT LOW ELECTRIC FIELD

Normally-Off GaN Field Effect Power Transistors: Device Design and Process Technology Development

Semiconductor Module

The effect of light illumination in photoionization of deep traps in GaN MESFETs buffer layer using an ensemble Monte Carlo simulation

Analytical Evaluation of Energy and Electron Concentrations in Quantum Wells of the High Electron Mobility Transistors.

GaN-based Devices: Physics and Simulation

51. IWK Internationales Wissenschaftliches Kolloquium International Scientific Colloquium

POLARIZATION INDUCED EFFECTS IN AlGaN/GaN HETEROSTRUCTURES

Electronic and Optoelectronic Properties of Semiconductor Structures

Supplementary Figure 1: SAW transducer equivalent circuit

Detectors of the Cryogenic Dark Matter Search: Charge Transport and Phonon Emission in Ge 100 Crystals at 40 mk

ELECTRONS AND PHONONS IN SEMICONDUCTOR MULTILAYERS

Simulation of GaN-based Light-Emitting Devices

Simulation of Power Heterojunction Bipolar Transistors on Gallium Arsenide

Basic Semiconductor Physics

Arizona State University, Tempe, AZ 85287, USA 2 Department of Electrical Engineering. Arizona State University, Tempe, AZ 85287, USA ABSTRACT

Optical Investigation of the Localization Effect in the Quantum Well Structures

Eldad Bahat-Treidel (Autor) GaN-Based HEMTs for High Voltage Operation: Design, Technology and Characterization

Performance Analysis of. doped and undoped AlGaN/GaN HEMTs

Energy dispersion relations for holes inn silicon quantum wells and quantum wires

Influence of Schottky Diode Modelling Under Flat-Band Conditions on the Simulation of Submillimeter-Wave Mixers

Atomistic effect of delta doping layer in a 50 nm InP HEMT

Resonant terahertz absorption by plasmons in grating-gate GaN HEMT structures

Semiconductor Physical Electronics

S-Parameter Simulation of RF-HEMTs

Electron Momentum and Spin Relaxation in Silicon Films

Emission Spectra of the typical DH laser

Carrier Dynamics in Quantum Cascade Lasers

Thermoelectric effects in wurtzite GaN and Al x Ga 1 x N alloys

Sergey SMIRNOV a),hanskosina, and Siegfried SELBERHERR, Nonmembers

Sheng S. Li. Semiconductor Physical Electronics. Second Edition. With 230 Figures. 4) Springer

Surfaces, Interfaces, and Layered Devices

2.4 GaAs Heterostructures and 2D electron gas

Effect of Piezoelectric Polarization on Phonon Relaxation Rates in Binary Wurtzite Nitrides

Minimal Update of Solid State Physics

GaN based transistors

16EC401 BASIC ELECTRONIC DEVICES UNIT I PN JUNCTION DIODE. Energy Band Diagram of Conductor, Insulator and Semiconductor:

GaN and GaN/AlGaN Heterostructure Properties Investigation and Simulations. Ziyang (Christian) Xiao Neil Goldsman University of Maryland

Nearly free electron model and k p method calculations of electronic band structure of wurtzite InN

Compound Semiconductors. Electronic Transport Characterization of HEMT Structures

MONTE CARLO MODELING OF HEAT GENERATION IN ELECTRONIC NANOSTRUCTURES

Infrared Reflectivity Spectroscopy of Optical Phonons in Short-period AlGaN/GaN Superlattices

ELECTRON MOBILITY CALCULATIONS OF n-inas

Dislocation scattering effect on two-dimensional electron gas transport in an GaN/AlGaN modulation-doped heterostructure

Influence of the doping element on the electron mobility in n-silicon

Studying of the Dipole Characteristic of THz from Photoconductors

Atlas III-V Advanced Material Device Modeling

Transport-to-Quantum Lifetime Ratios in AlGaN/GaN Heterostructures. L. Hsu. General College, University of Minnesota, Minneapolis, MN USA

Semiconductor Devices and Circuits Fall Midterm Exam. Instructor: Dr. Dietmar Knipp, Professor of Electrical Engineering. Name: Mat. -Nr.

Numerical calculation of the electron mobility in ZnS and ZnSe semiconductors using the iterative method

Integrated Circuits & Systems

Traps in MOCVD n-gan Studied by Deep Level Transient Spectroscopy and Minority Carrier Transient Spectroscopy

Electron leakage effects on GaN-based light-emitting diodes

Decay of spin polarized hot carrier current in a quasi. one-dimensional spin valve structure arxiv:cond-mat/ v1 [cond-mat.mes-hall] 10 Oct 2003

Fin and Island Isolation of AlGaN/GaN HFETs and Temperature-dependent Modeling of Drain Current Characteristics of AlGaN/GaN HFETs

PHYSICS OF SEMICONDUCTORS AND THEIR HETEROSTRUCTURES

A novel model of photo-carrier screening effect on the GaN-based p-i-n ultraviolet detector

Generalized Monte Carlo Tool for Investigating Low-Field. and High Field Properties of Materials Using. Non-parabolic Band Structure Model

Carrier Loss Analysis for Ultraviolet Light-Emitting Diodes

Low-Field Mobility and Quantum Effects in Asymmetric Silicon-Based Field-Effect Devices

Frequency Influence on the Hot-Electron Noise Reduction in GaAs Operating under Periodic Signals

OVER THE LAST several years, AIGaN/GaN HFETs

Carrier transport: Drift and Diffusion

Ultrafast All-optical Switches Based on Intersubband Transitions in GaN/AlN Multiple Quantum Wells for Tb/s Operation

INVESTIGATION OF SELF-HEATING AND MACROSCOPIC BUILT-IN POLARIZATION EFFECTS ON THE PERFORMANCE OF III-V NITRIDE DEVICES

Influence of excitation frequency on Raman modes of In 1-x Ga x N thin films

Crosslight Software Overview, New Features & Updates. Dr. Peter Mensz

NONLINEAR TRANSPORT IN BALLISTIC SEMICONDUCTOR DIODES WITH NEGATIVE EFFECTIVE MASS CARRIERS

DESIGN AND THEORETICAL STUDY OF WURTZITE GAN HEMTS AND APDS VIA ELECTROTHERMAL MONTE CARLO SIMULATION

Supplementary Figure 2 Photoluminescence in 1L- (black line) and 7L-MoS 2 (red line) of the Figure 1B with illuminated wavelength of 543 nm.

Current mechanisms Exam January 27, 2012

WIDE bandgap GaN-based high-electron mobility transistors

Journal of Atoms and Molecules

Supporting Information. by Hexagonal Boron Nitride

Ge Quantum Well Modulators on Si. D. A. B. Miller, R. K. Schaevitz, J. E. Roth, Shen Ren, and Onur Fidaner

SILICON-ON-INSULATOR (SOI) technology has been

Transcription:

Temperature Dependence of the Transport Properties of InN G. Aloise, S. Vitanov, and V. Palankovski ADVANCED MATERIAS AND DEVICE ANAYSIS GROUP INST. FOR MICROEECTRONICS TU Wien, A-1040 Vienna, Austria palankovski@iue.tuwien.ac.at Acknowledgments This work is supported by the Austrian Science Funds FWF, START Project No.Y247-N13. Keywords Indium Nitride, mobility model, temperature dependence, Gunn diode, device simulation Abstract In this work, we employ a Monte Carlo (MC) approach to investigate the temperature dependence of the electron transport in wurtzite InN. The velocity-field characteristics of this material show a pronounced negative differential resistance, which is a requirement for the realization of transferred-electron devices. Based on the Monte Carlo simulation results we derive a hydrodynamic mobility model suited for use in device simulation tools. As a particular example, we evaluate the performance of InN Gunn diodes using our twodimensional device simulator MINIMOS-NT. Introduction The research on InN is being boosted by its considerable potential for electronic and optoelectronic device applications. This material exhibits superior electron transport characteristics when compared to those of GaN [1, 2]. Theoretical studies [3, 4, 5] of InN predict a negative differential resistance (NDR) at high electric fields, which is a requirement for the occurrence of the Gunn effect. In addition, the electron mobility in InN is much higher than in GaN. This makes InN a strong candidate for use in the next generation transferredelectron devices, especially Gunn diodes for high-frequency applications. In this work we use a Monte Carlo approach to investigate the electron transport in InN at different temperatures, considering the band structure and scattering model parameters as described in [3]. In addition, we consider temperature-dependent lattice and elastic constants [6]. We rely on the obtained Monte Carlo results to construct an appropriate macroscopic model and implement it in our two dimensional device simulator MINIMOS-NT [7], which is used to evaluate the electrical and thermal performance of an InN-based Gunn diode. 77

The Monte Carlo Approach The Monte Carlo method is a powerful technique to establish a consistent link between theory and experiments. It helps to gain understanding of the transport properties, and it provides macroscopic parameters which are necessary for the description of electron devices. We employ a single-particle Monte Carlo technique to investigate stationary electron transport in InN [8, 9]. Our calculations include the three lowest valleys of the conduction band and account for non-parabolicity effects. Several stochastic mechanisms such as acoustic phonon, polar optical phonon, inter-valley phonon, Coulomb, and piezoelectric scattering are considered and their impact is assessed [3]. Temperature-dependent lattice and elastic constants [6] and the corresponding sound velocities in lateral and transversal direction are accounted for. The particular advantage of the Monte Carlo approach is that it provides a transport formulation on microscopic level, limited only by the extent to which the underlying physics of the system is included. Since the InN material system is yet not so well explored, several important input parameters are still missing or just not well known. Fig. 1: ow-field electron mobility as a function of lattice temperature in InN for different carrier concentrations. Fig. 2: ow-field electron mobility as a function of carrier concentration in InN for different lattice temperatures. Monte Carlo Simulation Results In Fig. 1 the temperature dependence of the low-field electron mobility for different doping concentrations is shown. A mobility value of above 10000 cm 2 /Vs for a doping level of 10 16 cm 3 at K is achieved. This value decreases to 2000 cm 2 /Vs at 600 K. For the technologically relevant concentration of 10 17 cm 3, the low-field electron mobility is found to decrease from 8000 cm 2 /Vs at K to about 2000 cm 2 /Vs at 600 K. In accordance with Fig. 2, the mobility reduction for higher doping levels with temperature is less. Fig. 3 shows the electron drift velocity as a function of the applied electric field for different temperatures. The strongest temperature dependence is seen near the peak velocity. At higher electric field, only a or impact is observed. 78

Fig. 3: Electron drift velocity dependence on electric field in InN for a carrier concentration of 10 17 cm 3 and different lattice temperatures. Fig. 4: Schematic of the Gunn diode and the resonant cavity. Mobility Model In order to properly model temperature effects in semiconductor devices, there is the need to derive an appropriate mobility model, that takes into account the relevant stochastic and scattering mechanisms considered in the Monte Carlo simulation. Such mobility models are derived for low-field as well as for high-field conditions. The model for the low-field condition is expressed as follows [10]: I 1 C C I ref γ 0 T K γ 1, T K γ 2, γ 3 ref ref T C C, K where is the electron mobility in undoped material, is the mobility at high doping, C ref and 0 model the mobility decay with rising impurity concentration C I. 1, 2 and 3 are used to model the mobility and concentration dependence on the lattice temperature T. The calibrated model parameter values are summarized in Table I. As can be seen in Fig. 1 and Fig. 2, these values provide an excellent agreement to the Monte Carlo simulation data. To model the high-field mobility in InN, a hydrodynamic transport model is employed [11], which accounts for intervalley transfer of electrons at higher electric fields and the subsequent abrupt decay in their velocity (Fig. 3). 79

Table I: Parameter values for the low-field InN mobility model. Ref. [cm 2 /Vs] [cm 2 /Vs] ref C [cm -3 ] 0 1 2 3 [13] 10200 500 3.4 10 17 0.65-2.7-2.7 4.5 This work 11980 700 2.2 10 17 0.65-2.6-0.6 4.2 Such high-field mobility model uses the already discussed low-field mobility expressions, constant energy relaxation times as taken from the Monte Carlo simulation, and the electron saturation velocity v sat as input parameters. While a detailed discussion of the model is given elsewhere [11], this work focuses on a profound description of the temperature-dependent parameters. The saturation velocity v sat is modelled as a function of lattice temperature by [12]: vsat, v sat ( T ) T (1 A) A K where v sat, is the saturation velocity at T = K and A is a parameter that models the v sat decay at higher temperatures. The values obtained after calibration against the Monte Carlo simulation data (v sat, =1.21 10 7 cm/s and A=0.3) ensure a proper approximation of the electron velocity dependence on lattice temperature at high electric fields (Fig. 3). The pronounced decrease of the peak electron velocity, observed for high applied fields, predicts the existence of a negative differential resistance for InN. This is a requirement for the occurrence of the Gunn effect. Device/Circuit Simulation Results In order to assess the influence of the temperature in a transferred-electron device, we construct an InN Gunn diode with an active layer (10 17 cm 3 ) of 3 μm length and two highlydoped (10 19 cm 3 ) contact regions of 0.1 μm each. The device of area 2000 m 2 is connected to a CR-cavity (=10 ph, C=0.1 pf, R=50, V 0 =13 V), so that it can operate as an oscillator (see Fig. 4). The temperature-dependent mobility model for InN, calibrated against the Monte Carlo simulation data, is implemented in MINIMOS-NT, which was already successfully employed for the high-temperature study of GaN-based high electron mobility transistors [14]. The simulation tool allows a mixed-mode device/circuit simulation of the Gunn diode. Fig. 5 shows voltage waveforms as resulting from isothermal simulation at different ambient temperatures. Fig. 6 shows the voltage waveforms when self-heating of the device is taken into consideration. The amplitude of the voltage oscillations decreases strongly with temperature for both conditions considered, which must be attributed to the temperature-driven decrease of the electron mobility. The output power of the diode is shown in Fig. 7, for isothermal conditions, and in Fig. 8 for self-heating respectively. A significant power decrease with increasing temperature is observed. At 500 K the swing of the output power waveforms is strongly damped. 80

Fig. 5: InN diode voltage waveforms for different temperatures and isothermal condition. Fig. 6: InN diode voltage waveforms for different temperatures when self-heating is considered. Fig. 7: InN diode output power for different temperatures and isothermal condition. Fig. 8: InN diode output power for different temperatures when self-heating is considered. Conclusion A temperature-dependent mobility model for InN is established based on Monte Carlo simulation results. It is implemented in a device simulation tool, which is used to evaluate the temperature-dependent performance of a InN Gunn diode oscillator. Our results show that the output power of the diode exhibits a strong temperature dependence, which is an important parameter to be accounted for when designing such devices for practical applications. 81

References [1] S. O eary, B. Foutz, M. Shur, U. Bhapkar, and. Eastman, Electron Transport in Wurtzite Indium Nitride, J.Appl.Phys., vol. 83, no. 2, pp. 826 829, 1998. [2] B. Foutz, S. O eary, M. Shur, and. Eastman, Transient Electron Transport in Wurtzite GaN, InN, and AlN, J.Appl.Phys., vol. 85, no. 11, pp. 7727 7734, 1999. [3] S. Vitanov and V. Palankovski, Monte Carlo Study of Transport Properties of InN, Springer Proc. in Physics, vol. 119, no. 2, pp. 97 100, 2007. [4] S. O eary, B. Foutz, M. Shur, and. Eastman, Electron Transport in Wurtzite Indium Nitride, J.Mater.Sci., vol. 21, no. 3, pp. 218 230, 2010. [5] V. Polyakov and F. Schwierz, Nonparabolicity Effect on Bulk Transport Properties in Wurtzite InN, J.Appl.Phys., vol. 99, no. 11, pp. 113705(6), 2006. [6] K. Wang and R. Reeber, Thermal Exapnsion and Elastic Properties of InN, Appl.Phys.ett., vol. 79, no. 11, pp. 1602 1604, 2001. [7] Minimos-NT Device and Circuit Simulator, User s Guide, http://www.iue.tuwien.ac.at/mmnt. [8] W. ambrecht and B. Segall, Properties of the Group III Nitrides, EMIS Datareview Series, 11, pp. 151 156, 1994. [9] D. Fritsch, Band Dispersion Relations of Zinc-Blende and Wurtzite InN, Phys.Rev.B, vol. 69, no. 16, pp. 165204-1 165204-5, 2004. [10] D. Caughey and R. Thomas, Carrier Mobilities in Silicon Empirically Related to Doping and Field, Proc.IEEE, vol. 55, pp. 2192 2193, 1967. [11] S. Vitanov, V. Palankovski, and S. Selberherr, Hydrodynamic Models for GaN-Based HEMTs, in Proc. European Solid-State Device Research Conf. ESSDERC, Fringe Poster Session, (Sevilla, Spain), CDROM, 4 pages, Sept. 2010. [12] V. Palankovski and R. Quay, Analysis and Simulation of Heterostructure Devices, Springer, Wien New York, 2004. [13] S. Vitanov and V. Palankovski, Normally-Off AlGaN/GaN HEMTs with InGaN Cap ayer: A Simulation Study, Solid State Electronics, vol. 52, no. 11, pp. 1791 1795, 2008. [14] S. Vitanov, V. Palankovski, S. Maroldt, and R. Quay, High-Temperature Modeling of AlGaN/GaN HEMTs, Solid State Electronics, vol. 54, no. 10, pp. 1105 1112, 2010. 82

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback