A Superlattice Infrared Photodetector Integrated With Multiple Quantum Wells to Improve the Performance

A Superlattice Infrared Photodetector Integrated With Multiple Quantum Wells to Improve the Performance

An infrared photodetector using the structure of a 15-period superlattice (SL) integrated with 50-period multiple quantum wells (MQWs) is investigated. The MQWs are utilized to reduce the noise current power and to add the response range. From the results of current ratio and response, the photocurr...

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Veröffentlicht in:IEEE journal of quantum electronics 2007-01, Vol.43 (1), p.72-77
Hauptverfasser: LU, Jen-Hsiang, WU, Kun-Jheng, HSIEH, Kuang-Jou, KUAN, Chieh-Hsiung, FENG, Juei-Yang, LAY, Tsong-Sheng, YANG, Chen-Wei, TU, Shun-Li
Format: Artikel
Sprache:eng
Schlagworte:
Applied sciences
Bias
Bolometer
infrared, submillimeter wave, microwave and radiowave receivers and detectors
Dark current
Electronics
Exact sciences and technology
Infrared
Infrared detectors
Infrared, submillimeter wave, microwave and radiowave instruments, equipment and techniques
Instruments, apparatus, components and techniques common to several branches of physics and astronomy
noise filter
Noise reduction
Optoelectronic devices
Photoconductivity
Photocurrent
Photodetectors
Photoelectric effect
photovoltaic (PV) detectors
Photovoltaic systems
Physics
Quantum well devices
Quantum wells
Semiconductor electronics. Microelectronics. Optoelectronics. Solid state devices
Solar power generation
Studies
superlattice
Superlattices
Temperature
Voltage
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Zusammenfassung:An infrared photodetector using the structure of a 15-period superlattice (SL) integrated with 50-period multiple quantum wells (MQWs) is investigated. The MQWs are utilized to reduce the noise current power and to add the response range. From the results of current ratio and response, the photocurrent of the SL is not reduced by the additional MQWs but the dark current is. Hence, due to the low noise gain and low dark current, the maximum detectivity (D * ) can occur at low negative bias. In addition, the photovoltaic response even appears at 80 K. It is observed that the photoelectron transport directions from the SL and the MQWs are opposite under zero bias. In comparison with the SL with a single barrier, this structure also demonstrates the higher photocurrent and lower dark current. From our experimental results, this structure is appropriate for the operation at low bias and high temperature. However, the tradeoff is the small operational voltage range
ISSN:0018-9197
1558-1713
DOI:10.1109/JQE.2006.884584