Photodetector Explained

Photodetectors, also called photosensors, are sensors of light or other electromagnetic radiation.[1] There are a wide variety of photodetectors which may be classified by mechanism of detection, such as photoelectric or photochemical effects, or by various performance metrics, such as spectral response. Semiconductor-based photodetectors typically use a p–n junction that converts photons into charge. The absorbed photons make electron–hole pairs in the depletion region. Photodiodes and photo transistors are a few examples of photo detectors. Solar cells convert some of the light energy absorbed into electrical energy.

Classification

Photodetectors can be classified based on their mechanism of operation and device structure. Here are the common classifications:

Based on mechanism of operation

Photodetectors may be classified by their mechanism for detection:[2] [3] [4]

Photodetectors may be used in different configurations. Single sensors may detect overall light levels. A 1-D array of photodetectors, as in a spectrophotometer or a Line scanner, may be used to measure the distribution of light along a line. A 2-D array of photodetectors may be used as an image sensor to form images from the pattern of light before it.

A photodetector or array is typically covered by an illumination window, sometimes having an anti-reflective coating.

Based on device structure

Based on device structure, photodetectors can be classified into the following categories:

  1. MSM Photodetector: A metal-semiconductor-metal (MSM) photodetector consists of a semiconductor layer sandwiched between two metal electrodes. The metal electrodes are interdigitated, forming a series of alternating fingers or grids. The semiconductor layer is typically made of materials such as silicon (Si), gallium arsenide (GaAs), indium phosphide (InP) or antimony selenide (Sb2Se3). Various methods are employed together to improve its characteristics, such as manipulating the vertical structure, etching, changing the substrate, and utilizing plasmonics.[8] The best achievable efficiency is shown by Antimony Selenide photodetectors.
  2. Photodiodes: Photodiodes are the most common type of photodetectors. They are semiconductor devices with a PN junction. Incident light generates electron-hole pairs in the depletion region of the junction, producing a photocurrent. Photodiodes can be further categorized into: a. PIN Photodiodes: These photodiodes have an additional intrinsic (I) region between the P and N regions, which extends the depletion region and improves the device's performance. b. Schottky Photodiodes: In Schottky photodiodes, a metal-semiconductor junction is used instead of a PN junction. They offer high-speed response and are commonly used in high-frequency applications.
  3. Avalanche Photodiodes (APDs): APDs are specialized photodiodes that incorporate avalanche multiplication. They have a high electric field region near the PN junction, which causes impact ionization and produces additional electron-hole pairs. This internal amplification improves the detection sensitivity. APDs are widely used in applications requiring high sensitivity, such as low-light imaging and long-distance optical communication.
  4. Phototransistors: Phototransistors are transistors with a light-sensitive base region. Incident light causes a change in the base current, which controls the transistor's collector current. Phototransistors offer amplification and can be used in applications that require both detection and signal amplification.
  5. Charge-Coupled Devices (CCDs): CCDs are imaging sensors composed of an array of tiny capacitors. Incident light generates charge in the capacitors, which is sequentially read and processed to form an image. CCDs are commonly used in digital cameras and scientific imaging applications.
  6. CMOS Image Sensors (CIS): CMOS image sensors are based on complementary metal-oxide-semiconductor (CMOS) technology. They integrate photodetectors and signal processing circuitry on a single chip. CMOS image sensors have gained popularity due to their low power consumption, high integration, and compatibility with standard CMOS fabrication processes.
  7. Photomultiplier Tubes (PMTs): PMTs are vacuum tube-based photodetectors. They consist of a photocathode that emits electrons when illuminated, followed by a series of dynodes that multiply the electron current through secondary emission. PMTs offer high sensitivity and are used in applications that require low-light detection, such as particle physics experiments and scintillation detectors.

These are some of the common photodetectors based on device structure. Each type has its own characteristics, advantages, and applications in various fields, including imaging, communication, sensing, and scientific research.

Properties

There are a number of performance metrics, also called figures of merit, by which photodetectors are characterized and compared

Subtypes

Grouped by mechanism, photodetectors include the following devices:

Photoemission or photoelectric

Semiconductor

Photovoltaic

Thermal

Photochemical

Polarization

Graphene/silicon photodetectors

A graphene/n-type silicon heterojunction has been demonstrated to exhibit strong rectifying behavior and high photoresponsivity. Graphene is coupled with silicon quantum dots (Si QDs) on top of bulk Si to form a hybrid photodetector. Si QDs cause an increase of the built-in potential of the graphene/Si Schottky junction while reducing the optical reflection of the photodetector. Both the electrical and optical contributions of Si QDs enable a superior performance of the photodetector.[19]

See also

Notes and References

  1. 10.1063/1.2884264. Study of residual background carriers in midinfrared InAs/GaSb superlattices for uncooled detector operation. 2008. Haugan. H. J.. Elhamri. S.. Szmulowicz. F.. Ullrich. B.. Brown. G. J.. Mitchel. W. C.. Applied Physics Letters. 92. 7. 071102. 2008ApPhL..92g1102H . 39187771 .
  2. Web site: Donati. S.. Photodetectors. unipv.it. Prentice Hall. 1 June 2016.
  3. Yotter. R.A.. Wilson. D.M.. A review of photodetectors for sensing light-emitting reporters in biological systems. IEEE Sensors Journal. June 2003. 3. 3. 288–303. 10.1109/JSEN.2003.814651. 2003ISenJ...3..288Y.
  4. Stöckmann. F.. Photodetectors, their performance and their limitations. Applied Physics. May 1975. 7. 1. 1–5. 10.1007/BF00900511. 1975ApPhy...7....1S. 121425624 .
  5. Singh . Yogesh . Kumar . Manoj . Yadav . Reena . Kumar . Ashish . Rani . Sanju . Shashi . Singh . Preetam . Husale . Sudhir . Singh . V. N. . 2022-08-15 . Enhanced photoconductivity performance of microrod-based Sb2Se3 device . Solar Energy Materials and Solar Cells . en . 243 . 111765 . 10.1016/j.solmat.2022.111765 . 0927-0248.
  6. A. Grinberg. Anatoly. Luryi. Serge. Theory of the photon-drag effect in a two-dimensional electron gas. Physical Review B. 1 July 1988. 38. 1. 87–96. 10.1103/PhysRevB.38.87. 9945167 . 1988PhRvB..38...87G.
  7. Bishop. P.. Gibson. A.. Kimmitt. M.. The performance of photon-drag detectors at high laser intensities. IEEE Journal of Quantum Electronics. October 1973. 9. 10. 1007–1011. 10.1109/JQE.1973.1077407. 1973IJQE....9.1007B.
  8. Singh . Yogesh . Parmar . Rahul . Srivastava . Avritti . Yadav . Reena . Kumar . Kapil . Rani . Sanju . Shashi . Srivastava . Sanjay K. . Husale . Sudhir . Sharma . Mahesh . Kushvaha . Sunil Singh . Singh . Vidya Nand . 2023-06-16 . Highly Responsive Near-Infrared Si/Sb 2 Se 3 Photodetector via Surface Engineering of Silicon . ACS Applied Materials & Interfaces . 15 . 25 . 30443–30454 . en . 10.1021/acsami.3c04043 . 1944-8244.
  9. Hu. Yue. Modeling sources of nonlinearity in a simple pin photodetector. Journal of Lightwave Technology. 1 October 2014. 32. 20. 3710–3720. 2014JLwT...32.3710H. 10.1109/JLT.2014.2315740. 10.1.1.670.2359. 9882873 .
  10. Web site: Photo Detector Circuit. oscience.info.
  11. Book: Pearsall. Thomas. Photonics Essentials, 2nd edition. McGraw-Hill. 2010. 978-0-07-162935-5. 2021-02-24. 2021-08-17. https://web.archive.org/web/20210817005021/https://www.mheducation.com/highered/product/photonics-essentials-second-edition-pearsall/9780071629355.html. dead.
  12. Web site: Encyclopedia of Laser Physics and Technology - photodetectors, photodiodes, phototransistors, pyroelectric photodetectors, array, powermeter, noise. Paschotta. Dr. Rüdiger. www.rp-photonics.com. 2016-05-31.
  13. Web site: PDA10A(-EC) Si Amplified Fixed Gain Detector User Manual. 24 April 2018. Thorlabs.
  14. Web site: DPD80 760nm Datasheet. 24 April 2018. Resolved Instruments.
  15. Fossum . E. R. . Hondongwa . D. B. . A Review of the Pinned Photodiode for CCD and CMOS Image Sensors . IEEE Journal of the Electron Devices Society . 2014 . 2 . 3 . 33–43 . 10.1109/JEDS.2014.2306412 . free .
  16. Web site: Silicon Drift Detectors. tools.thermofisher.com. Thermo Scientific.
  17. Book: Enss, Christian. Cryogenic Particle Detection. Springer, Topics in applied physics 99. 2005. 978-3-540-20113-7.
  18. Yuan. Hongtao. Liu. Xiaoge. Afshinmanesh. Farzaneh. Li. Wei. Xu. Gang. Sun. Jie. Lian. Biao. Curto. Alberto G.. Ye. Guojun. Hikita. Yasuyuki. Shen. Zhixun. Zhang. Shou-Cheng. Chen. Xianhui. Brongersma. Mark. Hwang. Harold Y.. Cui. Yi. Polarization-sensitive broadband photodetector using a black phosphorus vertical p–n junction. Nature Nanotechnology. 1 June 2015. 10. 8. 707–713. 10.1038/nnano.2015.112. 26030655. 2015NatNa..10..707Y. 1409.4729.
  19. Yu. Ting. Wang. Feng. Xu. Yang. Ma. Lingling. Pi. Xiaodong. Yang. Deren. Graphene Coupled with Silicon Quantum Dots for High-Performance Bulk-Silicon-Based Schottky-Junction Photodetectors. Advanced Materials. 28. 24. 4912–4919. 2016. 10.1002/adma.201506140. 27061073. 205267070 .