An optical transistor, also known as an optical switch or a light valve, is a device that switches or amplifies optical signals. Light occurring on an optical transistor's input changes the intensity of light emitted from the transistor's output while output power is supplied by an additional optical source. Since the input signal intensity may be weaker than that of the source, an optical transistor amplifies the optical signal. The device is the optical analog of the electronic transistor that forms the basis of modern electronic devices. Optical transistors provide a means to control light using only light and has applications in optical computing and fiber-optic communication networks. Such technology has the potential to exceed the speed of electronics[citation needed], while conserving more power. The fastest demonstrated all-optical switching signal is 900 attoseconds (attosecond =10^-18 second), which paves the way to develop ultrafast optical transistors.[1]
Since photons inherently do not interact with each other, an optical transistor must employ an operating medium to mediate interactions. This is done without converting optical to electronic signals as an intermediate step. Implementations using a variety of operating mediums have been proposed and experimentally demonstrated. However, their ability to compete with modern electronics is currently limited.
Optical transistors could be used to improve the performance of fiber-optic communication networks. Although fiber-optic cables are used to transfer data, tasks such as signal routing are done electronically. This requires optical-electronic-optical conversion, which form bottlenecks. In principle, all-optical digital signal processing and routing is achievable using optical transistors arranged into photonic integrated circuits.[2] The same devices could be used to create new types of optical amplifiers to compensate for signal attenuation along transmission lines.
A more elaborate application of optical transistors is the development of an optical digital computer in which signals are photonic (i.e., light-transmitting media) rather than electronic (wires). Further, optical transistors that operate using single photons could form an integral part of quantum information processing where they can be used to selectively address individual units of quantum information, known as qubits.
Optical transistors could in theory be impervious to the high radiation of space and extraterrestrial planets, unlike electronic transistors which suffer from Single-event upset.
Comparison with electronicsedit
The most commonly argued case for optical logic is that optical transistor switching times can be much faster than in conventional electronic transistors. This is due to the fact that the speed of light in an optical medium is typically much faster than the drift velocity of electrons in semiconductors.
Optical transistors can be directly linked to fiber-optic cables whereas electronics requires coupling via photodetectors and LEDs or lasers. The more natural integration of all-optical signal processors with fiber-optics would reduce the complexity and delay in the routing and other processing of signals in optical communication networks.
It remains questionable whether optical processing can reduce the energy required to switch a single transistor to be less than that for electronic transistors. To realistically compete, transistors require a few tens of photons per operation. It is clear, however, that this is achievable in proposed single-photon transistors[3][4] for quantum information processing.
Perhaps the most significant advantage of optical over electronic logic is reduced power consumption. This comes from the absence of capacitance in the connections between individual logic gates. In electronics, the transmission line needs to be charged to the signal voltage. The capacitance of a transmission line is proportional to its length and it exceeds the capacitance of the transistors in a logic gate when its length is equal to that of a single gate. The charging of transmission lines is one of the main energy losses in electronic logic. This loss is avoided in optical communication where only enough energy to switch an optical transistor at the receiving end must be transmitted down a line. This fact has played a major role in the uptake of fiber optics for long-distance communication but is yet to be exploited at the microprocessor level.
Besides the potential advantages of higher speed, lower power consumption and high compatibility with optical communication systems, optical transistors must satisfy a set of benchmarks before they can compete with electronics.[5] No single design has yet satisfied all these criteria whilst outperforming speed and power consumption of state of the art electronics.
The criteria include:
Fan-out - Transistor output must be in the correct form and of sufficient power to operate the inputs of at least two transistors. This implies that the input and output wavelengths, beam shapes and pulse shapes must be compatible.
Logic level restoration - The signal needs to be ‘cleaned’ by each transistor. Noise and degradations in signal quality must be removed so that they do not propagate through the system and accumulate to produce errors.
Logic level independent of loss - In optical communication, the signal intensity decreases over distance due to absorption of light in the fiber optic cable. Therefore, a simple intensity threshold cannot distinguish between on and off signals for arbitrary length interconnects. The system must encode zeros and ones at different frequencies, use differential signaling where the ratio or difference in two different powers carries the logic signal to avoid errors.
Implementationsedit
Several schemes have been proposed to implement all-optical transistors. In many cases, a proof of concept has been experimentally demonstrated. Among the designs are those based on:
in an optical cavity or microresonator, where the transmission is controlled by a weaker flux of gate photons[6][7]
in free space, i.e., without a resonator, by addressing strongly interacting Rydberg states[8][9]
a system of indirect excitons (composed of bound pairs of electrons and holes in double quantum wells with a static dipole moment). Indirect excitons, which are created by light and decay to emit light, strongly interact due to their dipole alignment.[10][11]
cavity switch modulates cavity properties in time domain for quantum information applications.[14]
nanowire-based cavities employing polaritonic interactions for optical switching[15]
silicon microrings placed in the path of an optical signal. Gate photons heat the silicon microring causing a shift in the optical resonant frequency, leading to a change in transparency at a given frequency of the optical supply.[16]
a dual-mirror optical cavity that holds around 20,000 cesium atoms trapped by means of optical tweezers and laser-cooled to a few microkelvin. The cesium ensemble did not interact with light and was thus transparent. The length of a round trip between the cavity mirrors equaled an integer multiple of the wavelength of the incident light source, allowing the cavity to transmit the source light. Photons from the gate light field entered the cavity from the side, where each photon interacted with an additional "control" light field, changing a single atom's state to be resonant with the cavity optical field, which changing the field's resonance wavelength and blocking transmission of the source field, thereby "switching" the "device". While the changed atom remains unidentified, quantum interference allows the gate photon to be retrieved from the cesium. A single gate photon could redirect a source field containing up to two photons before the retrieval of the gate photon was impeded, above the critical threshold for a positive gain.[17]
in a concentrated water solution containing iodide anions[18]
^Hui, Dandan; Alqattan, Husain; Zhang, Simin; Pervak, Vladimir; Chowdhury, Enam; Hassan, Mohammed Th. (2023-02-24). "Ultrafast optical switching and data encoding on synthesized light fields". Science Advances. 9 (8): eadf1015. doi:10.1126/sciadv.adf1015. ISSN 2375-2548. PMC9946343. PMID 36812316.
^Jin, C.-Y.; Wada, O. (March 2014). "Photonic switching devices based on semiconductor nano-structures". Journal of Physics D. 47 (13): 133001. arXiv:1308.2389. Bibcode:2014JPhD...47m3001J. doi:10.1088/0022-3727/47/13/133001. S2CID 118513312.
^Neumeier, L.; Leib, M.; Hartmann, M. J. (2013). "Single-Photon Transistor in Circuit Quantum Electrodynamics". Physical Review Letters. 111 (6): 063601. arXiv:1211.7215. Bibcode:2013PhRvL.111f3601N. doi:10.1103/PhysRevLett.111.063601. PMID 23971573. S2CID 29256835.
^Hong, F. Y.; Xiong, S. J. (2008). "Single-photon transistor using microtoroidal resonators". Physical Review A. 78 (1): 013812. Bibcode:2008PhRvA..78a3812H. doi:10.1103/PhysRevA.78.013812.
^Miller, D. A. B. (2010). "Are optical transistors the logical next step?" (PDF). Nature Photonics. 4 (1): 3–5. Bibcode:2010NaPho...4....3M. doi:10.1038/nphoton.2009.240.
^Chen, W.; Beck, K. M.; Bucker, R.; Gullans, M.; Lukin, M. D.; Tanji-Suzuki, H.; Vuletic, V. (2013). "All-Optical Switch and Transistor Gated by One Stored Photon". Science. 341 (6147): 768–70. arXiv:1401.3194. Bibcode:2013Sci...341..768C. doi:10.1126/science.1238169. PMID 23828886. S2CID 6641361.
^Clader, B. D.; Hendrickson, S. M. (2013). "Microresonator-based all-optical transistor". Journal of the Optical Society of America B. 30 (5): 1329. arXiv:1210.0814. Bibcode:2013JOSAB..30.1329C. doi:10.1364/JOSAB.30.001329. S2CID 119220800.
^Tiarks, D.; Baur, S.; Schneider, K.; Dürr, S.; Rempe, G. (2014). "Single-Photon Transistor Using a Förster Resonance". Physical Review Letters. 113 (5): 053602. arXiv:1404.3061. Bibcode:2014PhRvL.113e3602T. doi:10.1103/PhysRevLett.113.053602. PMID 25126919. S2CID 14870149.
^Andreakou, P.; Poltavtsev, S. V.; Leonard, J. R.; Calman, E. V.; Remeika, M.; Kuznetsova, Y. Y.; Butov, L. V.; Wilkes, J.; Hanson, M.; Gossard, A. C. (2014). "Optically controlled excitonic transistor". Applied Physics Letters. 104 (9): 091101. arXiv:1310.7842. Bibcode:2014ApPhL.104i1101A. doi:10.1063/1.4866855. S2CID 5556763.
^Kuznetsova, Y. Y.; Remeika, M.; High, A. A.; Hammack, A. T.; Butov, L. V.; Hanson, M.; Gossard, A. C. (2010). "All-optical excitonic transistor". Optics Letters. 35 (10): 1587–9. Bibcode:2010OptL...35.1587K. doi:10.1364/OL.35.001587. PMID 20479817.
^Arkhipkin, V. G.; Myslivets, S. A. (2013). "All-optical transistor using a photonic-crystal cavity with an active Raman gain medium". Physical Review A. 88 (3): 033847. Bibcode:2013PhRvA..88c3847A. doi:10.1103/PhysRevA.88.033847.
^Jin, C.-Y.; Johne, R.; Swinkels, M.; Hoang, T.; Midolo, L.; van Veldhoven, P.J.; Fiore, A. (Nov 2014). "Ultrafast non-local control of spontaneous emission". Nature Nanotechnology. 9 (11): 886–890. arXiv:1311.2233. Bibcode:2014NatNa...9..886J. doi:10.1038/nnano.2014.190. PMID 25218324. S2CID 28467862.
^Piccione, B.; Cho, C. H.; Van Vugt, L. K.; Agarwal, R. (2012). "All-optical active switching in individual semiconductor nanowires". Nature Nanotechnology. 7 (10): 640–5. Bibcode:2012NatNa...7..640P. doi:10.1038/nnano.2012.144. PMID 22941404.
^Varghese, L. T.; Fan, L.; Wang, J.; Gan, F.; Wang, X.; Wirth, J.; Niu, B.; Tansarawiput, C.; Xuan, Y.; Weiner, A. M.; Qi, M. (2012). "A Silicon Optical Transistor". Frontiers in Optics 2012/Laser Science XXVIII. Vol. 2012. pp. FW6C.FW66. doi:10.1364/FIO.2012.FW6C.6. ISBN978-1-55752-956-5. PMC5269724. PMID 28133636. {{cite book}}: |journal= ignored (help)
^Volz, J.; Rauschenbeutel, A. (2013). "Triggering an Optical Transistor with One Photon". Science. 341 (6147): 725–6. Bibcode:2013Sci...341..725V. doi:10.1126/science.1242905. PMID 23950521. S2CID 35684657.
optical, transistor, optical, transistor, also, known, optical, switch, light, valve, device, that, switches, amplifies, optical, signals, light, occurring, optical, transistor, input, changes, intensity, light, emitted, from, transistor, output, while, output. An optical transistor also known as an optical switch or a light valve is a device that switches or amplifies optical signals Light occurring on an optical transistor s input changes the intensity of light emitted from the transistor s output while output power is supplied by an additional optical source Since the input signal intensity may be weaker than that of the source an optical transistor amplifies the optical signal The device is the optical analog of the electronic transistor that forms the basis of modern electronic devices Optical transistors provide a means to control light using only light and has applications in optical computing and fiber optic communication networks Such technology has the potential to exceed the speed of electronics citation needed while conserving more power The fastest demonstrated all optical switching signal is 900 attoseconds attosecond 10 18 second which paves the way to develop ultrafast optical transistors 1 Since photons inherently do not interact with each other an optical transistor must employ an operating medium to mediate interactions This is done without converting optical to electronic signals as an intermediate step Implementations using a variety of operating mediums have been proposed and experimentally demonstrated However their ability to compete with modern electronics is currently limited Contents 1 Applications 2 Comparison with electronics 3 Implementations 4 See also 5 ReferencesApplications editOptical transistors could be used to improve the performance of fiber optic communication networks Although fiber optic cables are used to transfer data tasks such as signal routing are done electronically This requires optical electronic optical conversion which form bottlenecks In principle all optical digital signal processing and routing is achievable using optical transistors arranged into photonic integrated circuits 2 The same devices could be used to create new types of optical amplifiers to compensate for signal attenuation along transmission lines A more elaborate application of optical transistors is the development of an optical digital computer in which signals are photonic i e light transmitting media rather than electronic wires Further optical transistors that operate using single photons could form an integral part of quantum information processing where they can be used to selectively address individual units of quantum information known as qubits Optical transistors could in theory be impervious to the high radiation of space and extraterrestrial planets unlike electronic transistors which suffer from Single event upset Comparison with electronics editThe most commonly argued case for optical logic is that optical transistor switching times can be much faster than in conventional electronic transistors This is due to the fact that the speed of light in an optical medium is typically much faster than the drift velocity of electrons in semiconductors Optical transistors can be directly linked to fiber optic cables whereas electronics requires coupling via photodetectors and LEDs or lasers The more natural integration of all optical signal processors with fiber optics would reduce the complexity and delay in the routing and other processing of signals in optical communication networks It remains questionable whether optical processing can reduce the energy required to switch a single transistor to be less than that for electronic transistors To realistically compete transistors require a few tens of photons per operation It is clear however that this is achievable in proposed single photon transistors 3 4 for quantum information processing Perhaps the most significant advantage of optical over electronic logic is reduced power consumption This comes from the absence of capacitance in the connections between individual logic gates In electronics the transmission line needs to be charged to the signal voltage The capacitance of a transmission line is proportional to its length and it exceeds the capacitance of the transistors in a logic gate when its length is equal to that of a single gate The charging of transmission lines is one of the main energy losses in electronic logic This loss is avoided in optical communication where only enough energy to switch an optical transistor at the receiving end must be transmitted down a line This fact has played a major role in the uptake of fiber optics for long distance communication but is yet to be exploited at the microprocessor level Besides the potential advantages of higher speed lower power consumption and high compatibility with optical communication systems optical transistors must satisfy a set of benchmarks before they can compete with electronics 5 No single design has yet satisfied all these criteria whilst outperforming speed and power consumption of state of the art electronics The criteria include Fan out Transistor output must be in the correct form and of sufficient power to operate the inputs of at least two transistors This implies that the input and output wavelengths beam shapes and pulse shapes must be compatible Logic level restoration The signal needs to be cleaned by each transistor Noise and degradations in signal quality must be removed so that they do not propagate through the system and accumulate to produce errors Logic level independent of loss In optical communication the signal intensity decreases over distance due to absorption of light in the fiber optic cable Therefore a simple intensity threshold cannot distinguish between on and off signals for arbitrary length interconnects The system must encode zeros and ones at different frequencies use differential signaling where the ratio or difference in two different powers carries the logic signal to avoid errors Implementations editSeveral schemes have been proposed to implement all optical transistors In many cases a proof of concept has been experimentally demonstrated Among the designs are those based on electromagnetically induced transparency in an optical cavity or microresonator where the transmission is controlled by a weaker flux of gate photons 6 7 in free space i e without a resonator by addressing strongly interacting Rydberg states 8 9 a system of indirect excitons composed of bound pairs of electrons and holes in double quantum wells with a static dipole moment Indirect excitons which are created by light and decay to emit light strongly interact due to their dipole alignment 10 11 a system of microcavity polaritons exciton polaritons inside an optical microcavity where similar to exciton based optical transistors polaritons facilitate effective interactions between photons 12 photonic crystal cavities with an active Raman gain medium 13 cavity switch modulates cavity properties in time domain for quantum information applications 14 nanowire based cavities employing polaritonic interactions for optical switching 15 silicon microrings placed in the path of an optical signal Gate photons heat the silicon microring causing a shift in the optical resonant frequency leading to a change in transparency at a given frequency of the optical supply 16 a dual mirror optical cavity that holds around 20 000 cesium atoms trapped by means of optical tweezers and laser cooled to a few microkelvin The cesium ensemble did not interact with light and was thus transparent The length of a round trip between the cavity mirrors equaled an integer multiple of the wavelength of the incident light source allowing the cavity to transmit the source light Photons from the gate light field entered the cavity from the side where each photon interacted with an additional control light field changing a single atom s state to be resonant with the cavity optical field which changing the field s resonance wavelength and blocking transmission of the source field thereby switching the device While the changed atom remains unidentified quantum interference allows the gate photon to be retrieved from the cesium A single gate photon could redirect a source field containing up to two photons before the retrieval of the gate photon was impeded above the critical threshold for a positive gain 17 in a concentrated water solution containing iodide anions 18 See also editOptical network on chip Optical interconnect Optical switch Parallel optical interface Optical communication Optical fiber cable Photonics Optoelectronics Electronics Transistor Optical physics Light Photons Optics Lasers Diodes Semiconductors Electrical elements Electronic componentsReferences edit Hui Dandan Alqattan Husain Zhang Simin Pervak Vladimir Chowdhury Enam Hassan Mohammed Th 2023 02 24 Ultrafast optical switching and data encoding on synthesized light fields Science Advances 9 8 eadf1015 doi 10 1126 sciadv adf1015 ISSN 2375 2548 PMC 9946343 PMID 36812316 Jin C Y Wada O March 2014 Photonic switching devices based on semiconductor nano structures Journal of Physics D 47 13 133001 arXiv 1308 2389 Bibcode 2014JPhD 47m3001J doi 10 1088 0022 3727 47 13 133001 S2CID 118513312 Neumeier L Leib M Hartmann M J 2013 Single Photon Transistor in Circuit Quantum Electrodynamics Physical Review Letters 111 6 063601 arXiv 1211 7215 Bibcode 2013PhRvL 111f3601N doi 10 1103 PhysRevLett 111 063601 PMID 23971573 S2CID 29256835 Hong F Y Xiong S J 2008 Single photon transistor using microtoroidal resonators Physical Review A 78 1 013812 Bibcode 2008PhRvA 78a3812H doi 10 1103 PhysRevA 78 013812 Miller D A B 2010 Are optical transistors the logical next step PDF Nature Photonics 4 1 3 5 Bibcode 2010NaPho 4 3M doi 10 1038 nphoton 2009 240 Chen W Beck K M Bucker R Gullans M Lukin M D Tanji Suzuki H Vuletic V 2013 All Optical Switch and Transistor Gated by One Stored Photon Science 341 6147 768 70 arXiv 1401 3194 Bibcode 2013Sci 341 768C doi 10 1126 science 1238169 PMID 23828886 S2CID 6641361 Clader B D Hendrickson S M 2013 Microresonator based all optical transistor Journal of the Optical Society of America B 30 5 1329 arXiv 1210 0814 Bibcode 2013JOSAB 30 1329C doi 10 1364 JOSAB 30 001329 S2CID 119220800 Gorniaczyk H Tresp C Schmidt J Fedder H Hofferberth S 2014 Single Photon Transistor Mediated by Interstate Rydberg Interactions Physical Review Letters 113 5 053601 arXiv 1404 2876 Bibcode 2014PhRvL 113e3601G doi 10 1103 PhysRevLett 113 053601 PMID 25126918 S2CID 20939989 Tiarks D Baur S Schneider K Durr S Rempe G 2014 Single Photon Transistor Using a Forster Resonance Physical Review Letters 113 5 053602 arXiv 1404 3061 Bibcode 2014PhRvL 113e3602T doi 10 1103 PhysRevLett 113 053602 PMID 25126919 S2CID 14870149 Andreakou P Poltavtsev S V Leonard J R Calman E V Remeika M Kuznetsova Y Y Butov L V Wilkes J Hanson M Gossard A C 2014 Optically controlled excitonic transistor Applied Physics Letters 104 9 091101 arXiv 1310 7842 Bibcode 2014ApPhL 104i1101A doi 10 1063 1 4866855 S2CID 5556763 Kuznetsova Y Y Remeika M High A A Hammack A T Butov L V Hanson M Gossard A C 2010 All optical excitonic transistor Optics Letters 35 10 1587 9 Bibcode 2010OptL 35 1587K doi 10 1364 OL 35 001587 PMID 20479817 Ballarini D De Giorgi M Cancellieri E Houdre R Giacobino E Cingolani R Bramati A Gigli G Sanvitto D 2013 All optical polariton transistor Nature Communications 4 1778 arXiv 1201 4071 Bibcode 2013NatCo 4 1778B doi 10 1038 ncomms2734 PMID 23653190 S2CID 11160378 Arkhipkin V G Myslivets S A 2013 All optical transistor using a photonic crystal cavity with an active Raman gain medium Physical Review A 88 3 033847 Bibcode 2013PhRvA 88c3847A doi 10 1103 PhysRevA 88 033847 Jin C Y Johne R Swinkels M Hoang T Midolo L van Veldhoven P J Fiore A Nov 2014 Ultrafast non local control of spontaneous emission Nature Nanotechnology 9 11 886 890 arXiv 1311 2233 Bibcode 2014NatNa 9 886J doi 10 1038 nnano 2014 190 PMID 25218324 S2CID 28467862 Piccione B Cho C H Van Vugt L K Agarwal R 2012 All optical active switching in individual semiconductor nanowires Nature Nanotechnology 7 10 640 5 Bibcode 2012NatNa 7 640P doi 10 1038 nnano 2012 144 PMID 22941404 Varghese L T Fan L Wang J Gan F Wang X Wirth J Niu B Tansarawiput C Xuan Y Weiner A M Qi M 2012 A Silicon Optical Transistor Frontiers in Optics 2012 Laser Science XXVIII Vol 2012 pp FW6C FW66 doi 10 1364 FIO 2012 FW6C 6 ISBN 978 1 55752 956 5 PMC 5269724 PMID 28133636 a href Template Cite book html title Template Cite book cite book a journal ignored help Volz J Rauschenbeutel A 2013 Triggering an Optical Transistor with One Photon Science 341 6147 725 6 Bibcode 2013Sci 341 725V doi 10 1126 science 1242905 PMID 23950521 S2CID 35684657 Buchmann A Hoberg C Novelli F 2022 An ultra fast liquid switch for terahertz radiation APL Photonics 7 121302 121302 Bibcode 2022APLP 7l1302B doi 10 1063 5 0130236 Retrieved from https en wikipedia org w index php title Optical transistor amp oldid 1215871094, wikipedia, wiki, book, books, library,
