High Operating Temperature (HOT) Split-off Band IR Detectors

Slides:

Advertisements

Similar presentations

Light Unit David B. Brown 6C.

Advertisements

RADIO WAVES, MICROWAVES, INFRARED, VISIBLE, ULTRAVIOLET, X-RAYS, GAMMA RAYS HIGH< wavelength LOW.

Electro-magnetic radiation

P.V.V. Jayaweera Institute of Fundamental Studies Hantana Road, Kandy.

High Operation Temperature (HOT) Split-off Band IR Detectors

1 Viraj Jayaweera Department of Physics Astronomy.

LECTURE- 5 CONTENTS  PHOTOCONDUCTING MATERIALS  CONSTRUCTION OF PHOTOCONDUCTING MATERIALS  APPLICATIONS OF PHOTOCONDUCTING MATERIALS.

Light Waves Electromagnetic waves that radiate Made of small pieces or particles of “light” energy called photons The more particles you put in front.

Astronomy and the Electromagnetic Spectrum

ASTRONOMY 161 Introduction to Solar System Astronomy Class 9.

Waves in Space—Transferring Energy

Electromagnetic Waves. Electromagnetic wave is a wave that can travel through empty space or through matter and is produced by charged particles that.

Chapter 18: Electromagnetic Waves Section 1: What are electromagnetic waves? Section 2: The Electromagnetic Spectrum.

 Electromagnetic Radiation-transverse energy waves produced by electrically charged particles.  Has the properties of both waves and particles.  These.

Quantum Well Infrared Detector

9. Semiconductors Optics Absorption and gain in semiconductors Principle of semiconductor lasers (diode lasers) Low dimensional materials: Quantum wells,

Principle of Diode LASER Laser 2

Improving Uncertainties of Non-Contact Thermometry Measurements Mark Finch Fluke Calibration.

Radiation Detection and Measurement II IRAD 2731.

Common types of spectroscopy

Electromagnetic Waves Objectives

Chapter 4 Photonic Sources.

Electromagnetic Waves

Solar Cells, Sluggish Capacitance, and a Puzzling Observation Tim Gfroerer Davidson College, Davidson, NC with Mark Wanlass National Renewable Energy Lab,

Electromagnetic Radiation. Is light a wave or a particle? Yes It’s both, and neither At atomic scales, we have no exact analogs for phenomena For some.

Visible light and the electromagnetic spectrum. we can’t see all types of light! Visible light is a very small part of a large range of radiations. It.

Atomic Theory and Spectroscopy Clues to the Nature of Atoms.

References Hans Kuzmany : Solid State Spectroscopy (Springer) Chap 5 S.M. Sze: Physics of semiconductor devices (Wiley) Chap 13 PHOTODETECTORS Detection.

Optical Characterization of GaN-based Nanowires : From Nanometric Scale to Light Emitting Devices A-L. Bavencove*, E. Pougeoise, J. Garcia, P. Gilet, F.

Electromagnetic Waves 18.1 p Electromagnetic Waves Are transverse waves consisting of changing electric fields and changing magnetic fields They.

Semiconductors. Direct bandgap semiconductors (GaAs, InGaAs, InGaAsP) The minimum of CB is directly above the maximum of VB Electro-hole pair can recombine.

Optoelectronics Radiometry and Photometry, Emitters and Receivers.

Electromagnetic Waves

NATURE OF LIGHT.  The electromagnetic spectrum comprise of the following:  1. Radio waves  Electromagnetic radiation with wavelengths that range from.

References Hans Kuzmany : Solid State Spectroscopy (Springer) Chap 5 S.M. Sze Physics of semiconductor devices (Wiley) Chap 13 PHOTODETECTORS.

Heat Transfer  How does the energy move from a hotter to a colder object?  Three mechanisms  Conduction  Convection  Radiation.

Spectrophotometry.

Electromagnetic Spectrum. Different Types of Light  Light is a form of energy  It travels in waves  Also called Electromagnetic Radiation  Some Electromagnetic.

Heterostructures & Optoelectronic Devices

24.1 The Study of Light Electromagnetic Radiation

Energy Kinetic Energy Potential Energy.

Electromagnetic waves are formed when an electric field couples with a magnetic field. The magnetic and electric fields of an electromagnetic wave are.

Mechanical, Electromagnetic, Electrical, Chemical and Thermal.

Optoelectronics.

Radiation (Ch 12 YAC) Thermal energy is emitted by matter as a result of vibrational and rotational motion of molecules, atoms and electrons. The energy.

Do Now: Based on the notes from last week, what is the difference between temperature and heat?

Solar Cell Semiconductor Physics

Infrared Infrared radiation extends from the nominal red edge of the visible spectrum at 700 nanometers (nm) to 1 mm. NameWavelength Gamma rayless than.

Electromagnetic Waves Chapter 12. What is an Electromagnetic Wave? Electromagnetic wave – is made by vibrating electric charges and can travel through.

ELECTROMAGNETIC WAVES AND LIGHT. ELECTROMAGNETIC WAVES Electromagnetic Waves travel through empty space or through matter and are produced by charged.

Important Terms Feb. 12, Conductor Materials that transfer (or conduct) heat well are known as conductors. Metals are the best conductors. Why?

Infrared IR Sensor Circuit Diagram and Working Principle.

Electromagnetic Radiation. LIGHT Electric fields Exist around electric charges Moving electric fields create magnetic fields Magnetic field perpendicular.

Electromagnetic Spectrum Foldable Instructions

 A system of satellites, ground monitoring stations, and receivers that determine your exact location at or above Earth’s surface.  Global Positioning.

Bandgap (eV) Lattice Constant (Å) Wavelength ( ㎛ ) GaN AlN InN 6H-SiC ZnO AlP GaP AlAs.

The Study of Light. The Electromagnetic Spectrum  includes gamma rays, X-rays, ultraviolet light, visible light, infrared radiation, microwaves, and.

The Electromagnetic Spectrum Scripps Classroom Connection

The Study of Light.

Physical Principles of Remote Sensing: Electromagnetic Radiation

P- type Si Homojunction Interfacial Workfunction Internal Photoemission Dual-Band Detector Responding in Near- and Far-Infrared Regions G. Ariyawansa.

Infra-red Radiation and William Herschel

High Operating Temperature Split-off Band IR Detectors

OPTICAL SOURCE : Light Emitting Diodes (LEDs)

Electromagnetic Spectrum Project

ELECTROMAGNETIC WAVES AND LIGHT

(EMR) Electromagnetic Radiation

Introduction and Basic Concepts

Radiation Heat Transfer

Presentation transcript:

High Operating Temperature (HOT) Split-off Band IR Detectors Viraj Jayaweera

Outline Introduction IR Range, Applications, Types of IR detectors Interfacial Workfunction Internal Photoemission (IWIP) Detectors Detector Structure, HIWIP & HEWIP Mechanisms Detector Measurements and Characterization Split-off Band Detectors Possible Material Systems to Extend Spectral Range Conclusion and Future Studies

Discovery of Infrared Sir Frederick William Herschel (1738-1822) musician and an astronomer famous for his discovery of the planet Uranus in 1781 Discovered “calorific rays” in 1800 later renamed as “Infrared rays”

(the prefix infra means `below‘) What is Infrared (IR) ? (the prefix infra means `below‘) The electromagnetic spectrum includes gamma rays, X-rays, ultraviolet, visible, infrared, microwaves, and radio waves. The only difference between these different types of radiation is their wavelength or frequency.

Infrared is usually divided into 3 spectral regions Micro wave Visible near-IR mid-IR Far-IR 0.8 – 5 m 5 - 40 m 40 - 250 m Can’t see (human eye) = 0.75 m Some animals can "see" in the infrared. For example, snakes in the pit viper family (e.g. rattlesnakes) have sensory "pits," which are used to detect infrared light. This allows the snake to find warm-blooded animals.

This is the radiation produced by the motion of atoms and molecules in an object. Any object which has a temperature above absolute zero (0 K) radiates infrared. person holding burning match Cat Infrared image of Orion Landing space shuttle Application: biophysics, communication, remote sensing, medical imaging, security and astrophysics.

Human & vehicle at total darkness thermal image in white=hot mode same image in Black=hot mode Human Suspect climbing over fence at 2:49 AM in total darkness Suspect attempting to burglarize vehicle at 1:47 AM in total darkness.

Pyroelectric Detectors Types of IR Detector IR Detectors Photon Detectors Pyroelectric Detectors Thermal Detectors Photo Conductive Photo Conductive Photovoltaic Bolometer Thermopile Interfacial Workfunction Internal Photoemission (IWIP) Detectors Homojunction IWIP = HIWIP Heterojunction IWIP = HEIWIP

Real Detector

Structure of the Interfacial Workfunction Internal Photoemission Detector. ~0.5mm Au contact layers Top Contact p++ GaAs N Periods p+ GaAs (emitter) GaAs (barrier) Homojunction Heterojunction p+ GaAs (emitter) AlGaAs (barrier) Bottom Contact p++ GaAs Substrate (photo conductive type)

HIWIP Barrier formed by Homojunction (n-type) (Homojunction Interfacial Workfunction Internal Photoemission Detector) n+ i n+ doped GaAs GaAs e- hν Δ Δ EF ECn zero bias biased Barrier formed by Homojunction (n-type) (Interfacial Workfunction Δ comes from doping) JAP 77, 915 (1995)

Barrier formed by Heterojunction (n-type) HEIWIP (HEterojunction Interfacial Workfunction Internal Photoemission Detector) n+ i n+ GaAs AlGaAs e- hν Δ Δ zero bias biased Barrier formed by Heterojunction (n-type) Interfacial Workfunction Δ comes from Al fraction and doping (Δ = Δd + Δx) Absorption is due to free carriers Interface is sharp (no space charge) APL 78, 2241 (2001) APL 82, 139 (2003)

Barrier formed by Heterojunction (p-type) HEIWIP (HEterojunction Interfacial Workfunction Internal Photoemission Detector) p+ GaAs AlGaAs h+ i p+ hν Δ biased Δ zero bias Barrier formed by Heterojunction (p-type) Interfacial Workfunction Δ comes from Al fraction and doping (Δ = Δd + Δx) Absorption is due to free carriers Interface is sharp (no space charge) APL 78, 2241 (2001) APL 82, 139 (2003)

Measurements and Characterization (IVT) Current Voltage Temperature measurements Using IVT measurements … Uniformity of sample (dark current density vs. voltage plot) Dark Current Variation with bias Voltage and Temperature Background Limited Infrared Photon detector (BLIP) Temperature Interfacial Workfunction (Δ) (slope of ln(I/T1.5) vs. 1/T plot) Switching System Source Meter He closed-cycle refrigerator head Vacuum Sample Temperature Controller PC V Log (I) Cold finger Radiation shield

time (mirror position) Measurements and Characterization time (mirror position) output energy Spectral Response Source Moving mirror Sample RL Output Wave number output energy Fourier transformation Beam splitter o Threshold wavelength Fixed mirror FTIR Spectrometer

# of electrons produced Quantum Efficiency (η) = # of photons insident Detector Output Responsivity (R) = Radiation Input # of electrons produced Quantum Efficiency (η) = # of photons insident Radiant flux necessary to give an output signal equal to the r.m.s. noise output of the detector Noise Equivalent Power (NEP) = 1 Detectivity (D*) = NEP

Split-off Response Quantum Efficiency Wavelength (µm) Sample 1332 2.5 5.0 7.5 10.0 12.5 15.0 0.00 0.01 0.02 Split-off Response Free Carrier Quantum Efficiency Wavelength (µm) Sample 1332 T = 50K

Split-off Response of the Detector HE0204 Under Different Temperatures

Detector mechanism consisting of three processes k Heavy Hole Band Light Hole Band Split-off Band Ef ESO Detector mechanism consisting of three processes Photoabsorption. (produces excited carriers) Carrier escape. Sweep out and collection of the escaped carriers.

Free Carrier Absorption Response Mechanism I Light/Heavy Hole Band E k Ef ΔL/H Free Carrier Absorption escape Heavy Hole Band Light Hole Band ΔSO Split-off Band Split-off Band The photoexcitation process consists of the standard free carrier absorption.

Response Mechanism II Light/Heavy Hole Band E k Ef ΔL/H Split-off Absorption Heavy Hole Band escape Light Hole Band scattering ΔSO Split-off Band Split-off Band direct photoabsorption to the split-off band, followed by a scattering to the light/heavy hole band.

Response Mechanism III Light/Heavy Hole Band E k Ef ΔL/H Split-off Absorption Heavy Hole Band Light Hole Band ΔSO Split-off Band Split-off Band escape Single indirect photoabsorption into the split-off band.

Response Mechanism IV Light/Heavy Hole Band E k Ef ΔL/H Split-off Absorption Heavy Hole Band escape Light Hole Band scattering ΔSO Split-off Band Split-off Band indirect photoabsorption, followed by a scattering event to the light or heavy hole band.

The Split-off Band Offset Energy for Different Materials ΔSO (meV) λSO (μm) Elh (meV) Eso InN 3 410 -790 -793 GaN 20 62 -1840 -1860 AlN 19 65 -2640 -2660 InP 108 11 -140 -248 GaP 80 16 -470 -550 AlP 70 18 -940 -1010 InAs 390 3.2 +210 -180 GaAs 340 3.6 +0 -340 AlAs 280 4.4 -530 -810 The energies of the light/heavy hole band (Elh) and the split-off hole band (ESO) relative to the valance band maximum of GaAs.

Conclusion and Future Studies High Operating Temperature The devices tested with a threshold of ~20 µm showed a maximum operating temperature of 130 K. By reducing the threshold to ~5 µm, the operating temperature should be increased to 300 K with D* of ~5×109 Jones. Increase Quantum efficiency Absorption efficiency can be increase by Increasing the no of emitter layers Increasing the doping to the maximum possible value Device Design for a 15 μm Detector Operating at 200K Device will based on p-doped GaP emitters and undoped AlGaP barriers.

Thank You