Presentation is loading. Please wait.

Presentation is loading. Please wait.

High-Power High-Efficiency Photodiode for Advanced LIGO

Published byJennifer Boone Modified over 8 years ago

Similar presentations

Presentation on theme: "High-Power High-Efficiency Photodiode for Advanced LIGO"— Presentation transcript:

1 High-Power High-Efficiency Photodiode for Advanced LIGO
LIGO-G Z David Jackrel Ph.D. Candidate- Dept. of Materials Science & Eng. Advisor- Dr. James S. Harris August 14th, 2001

2 Outline Introduction Experimental Results Development Plan
Photodiode Specifications Device Structure & Materials Experimental Results DC Response RF Response Development Plan InGaAs GaInNAs

3 Photodiode Specifications?
Parameter LIGO I Advanced LIGO Steady-State Power 0.6 W 1~10 W Operating Frequency  29 MHz 100 kHz ~ 180 MHz Quantum Efficiency  80%  90% Detector Design Bank of 6(+) PDs 1 PD

4 P-I-N Device Characteristics
Large E-field in I- region Depletion Width  Width of I- region RC time constant Tuned to a specific 

5 Heterojunction Band Gap Diagram
 = 1.064m  h = 1.17eV Absorption occurs in i-region InAlAs Optically transparent to 1.06m radiation n- p- i- N-layer: In.22Al.78As Eg2=1.8eV I-layer: In.22Ga.78As Eg1=1.1eV P-layer: In.22Al.78As Eg2=1.8eV

6 Rear-Illuminated PD Advantages
High Power High Speed Linear Response Conventional PD Adv. LIGO Rear-Illuminated PD

7 InGaAs/GaAs PD Structure
MBE GaAs Substrate InGaAs for i-layer InAlAs for the n- and p- layers Graded Buffer layer AR coating & Au/Pt contacts 2 m

8 III-V Lattice Constants and Band Gaps
InAlAs and InGaAs well lattice matched InAlAs much wider band gap

9 TEM Images of Confined Dislocations
Device Layers: -few dislocations Graded Buffer: -many dislocations

10 Nd:YAG (NPRO) PD Test Setup
RF Amplitude Modulator Power Meter PD Power Control NPRO (800mW)

11 Quantum Efficiency: #673 30% Loss

12 QE: Power & Bias Effects

13 DC Response Linearity: #673

14 RF Response: 3dB Bandwidth
~4MHz, 3dB-Bandwidth  ~5nF Capacitance

15 C-V Characteristics (#673)
 depletion width 1.44 m ~2.16m

16 InGaAs Development Plan
Goals: by Sept. 2002… 90% QE Thin substrates to 50m-100m Maximize Bandwidth Optimize illuminated area

17 GaInNAs Lattice-Matched to GaAs
GaInNAs- Adv LIGO InGaAs- LIGO I PD

18 Conclusion Introduction Experimental Results Development Plan
Photodiode Specifications Device Structure & Materials  InGaAs RI PIN PD Experimental Results DC Response  70% QE RF Response  4MHz 3-dB Bandwidth Development Plan InGaAs GaInNAs

Download ppt "High-Power High-Efficiency Photodiode for Advanced LIGO"

Similar presentations

Chapter 9. PN-junction diodes: Applications

Chapter 9. PN-junction diodes: Applications
Record Values of Electron Beam Polarization and Quantum Efficiency for Semiconductor Photocathodes Yu.A.Mamaev St. Petersburg State Polytechnic University.

Record Values of Electron Beam Polarization and Quantum Efficiency for Semiconductor Photocathodes Yu.A.Mamaev St. Petersburg State Polytechnic University.
Report for China Frontier Workshop (June 22nd 2006 Beijing) Wang Zhanguo Key Lab. of Semiconductor Materials Science, Institute of Semiconductors, Chinese.

Report for China Frontier Workshop (June 22nd 2006 Beijing) Wang Zhanguo Key Lab. of Semiconductor Materials Science, Institute of Semiconductors, Chinese.
Semiconductor Optical Sources

Semiconductor Optical Sources
Laser III Device Design & Materials Selection

Laser III Device Design & Materials Selection
© S.N. Sabki Revision CHAPTER 9 CHAPTER 9 Part II.

© S.N. Sabki Revision CHAPTER 9 CHAPTER 9 Part II.
High Brightness LEDs Chapter5 Chapter6 屠嫚琳.

High Brightness LEDs Chapter5 Chapter6 屠嫚琳.
Radiative efficiency of light-emitting materials Tim Gfroerer Davidson College, Davidson, NC - Funded by Research Corporation and the Petroleum Research.

Radiative efficiency of light-emitting materials Tim Gfroerer Davidson College, Davidson, NC - Funded by Research Corporation and the Petroleum Research.
Strain-Balanced Quantum Well Solar Cells From Multi-Wafer Production Jessica Adams 33 rd IEEE Photovoltaic Specialists Conference 12 th May 2008.

Strain-Balanced Quantum Well Solar Cells From Multi-Wafer Production Jessica Adams 33 rd IEEE Photovoltaic Specialists Conference 12 th May 2008.
Optoelectronic Devices (brief introduction)

Optoelectronic Devices (brief introduction)
Tin Based Absorbers for Infrared Detection, Part 2 Presented By: Justin Markunas Direct energy gap group IV semiconductor alloys and quantum dot arrays.

Tin Based Absorbers for Infrared Detection, Part 2 Presented By: Justin Markunas Direct energy gap group IV semiconductor alloys and quantum dot arrays.
Finite element simulations of compositionally graded InGaN solar cells G.F. Brown a,b,*, J.W.AgerIIIb, W.Walukiewicz b, J.Wua, b,a Advisor: H.C. Kuo Reporter:

Finite element simulations of compositionally graded InGaN solar cells G.F. Brown a,b,*, J.W.AgerIIIb, W.Walukiewicz b, J.Wua, b,a Advisor: H.C. Kuo Reporter:
EE 230: Optical Fiber Communication Lecture 11 From the movie Warriors of the Net Detectors.

EE 230: Optical Fiber Communication Lecture 11 From the movie Warriors of the Net Detectors.
Studies of Minority Carrier Recombination Mechanisms in Beryllium Doped GaAs for Optimal High Speed LED Performance An Phuoc Doan Department of Electrical.

Studies of Minority Carrier Recombination Mechanisms in Beryllium Doped GaAs for Optimal High Speed LED Performance An Phuoc Doan Department of Electrical.
9. Semiconductors Optics Absorption and gain in semiconductors Principle of semiconductor lasers (diode lasers) Low dimensional materials: Quantum wells,

9. Semiconductors Optics Absorption and gain in semiconductors Principle of semiconductor lasers (diode lasers) Low dimensional materials: Quantum wells,
Photo Detectors Parameters: Parameters: Responsivity (Efficiency): Output current/input optical powerResponsivity (Efficiency): Output current/input optical.

Photo Detectors Parameters: Parameters: Responsivity (Efficiency): Output current/input optical powerResponsivity (Efficiency): Output current/input optical.
Chapter 6 Photodetectors.

Chapter 6 Photodetectors.
4/11/2006BAE 54131 Application of photodiodes A brief overview.

4/11/2006BAE Application of photodiodes A brief overview.
V. Semiconductor Photodetectors (PD)

V. Semiconductor Photodetectors (PD)
A Bias-Dependent Equivalent-Circuit Model of Evanescently Coupled Photodiode (ECPD) Advisers : J.- W. Shi, Y.- J. Chan Student : Y.- S. Wu.

A Bias-Dependent Equivalent-Circuit Model of Evanescently Coupled Photodiode (ECPD) Advisers : J.- W. Shi, Y.- J. Chan Student : Y.- S. Wu.

Similar presentations

Ads by Google