Roadmap on Integrated Quantum Photonics

Integrated photonics is at the heart of many classical technologies, from optical communications to biosensors, LIDAR, and data center fiber interconnects. There is strong evidence that these integrated technologies will play a key role in quantum systems as they grow from few-qubit prototypes to te...

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Veröffentlicht in:	arXiv.org 2021-09
Hauptverfasser:	Moody, Galan, Sorger, Volker J, Blumenthal, Daniel J, Juodawlkis, Paul W, Loh, William, Sorace-Agaskar, Cheryl, Jones, Alex E, Balram, Krishna C, Matthews, Jonathan C F, Laing, Anthony, Davanco, Marcelo, Chang, Lin, Bowers, John E, Quack, Niels, Galland, Christophe, Aharonovich, Igor, Wolff, Martin A, Schuck, Carsten, Sinclair, Neil, Lončar, Marko, Komljenovic, Tin, Weld, David, Mookherjea, Shayan, Buckley, Sonia, Radulaski, Marina, Reitzenstein, Stephan, Pingault, Benjamin, Bartholomeus Machielse, Mukhopadhyay, Debsuvra, Akimov, Alexey, Zheltikov, Aleksei, Agarwal, Girish S, Srinivasan, Kartik, Lu, Juanjuan, Tang, Hong X, Jiang, Wentao, McKenna, Timothy P, Safavi-Naeini, Amir H, Steinhauer, Stephan, Elshaari, Ali W, Zwiller, Val, Davids, Paul S, Martinez, Nicholas, Gehl, Michael, Chiaverini, John, Mehta, Karan K, Romero, Jacquiline, Lingaraju, Navin B, Weiner, Andrew M, Peace, Daniel, Cernansky, Robert, Lobino, Mirko, Diamanti, Eleni, Luis Trigo Vidarte, Camacho, Ryan M
Format:	Artikel
Sprache:	eng
Schlagworte:	Circuit design Circuits Electron tubes Electronic circuits Electronic components Engineers Integrated circuits Photonics Physics - Quantum Physics Quantum computing Qubits (quantum computing) Racks Transistors Tunable lasers Vacuum tubes
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creator	Moody, Galan Sorger, Volker J Blumenthal, Daniel J Juodawlkis, Paul W Loh, William Sorace-Agaskar, Cheryl Jones, Alex E Balram, Krishna C Matthews, Jonathan C F Laing, Anthony Davanco, Marcelo Chang, Lin Bowers, John E Quack, Niels Galland, Christophe Aharonovich, Igor Wolff, Martin A Schuck, Carsten Sinclair, Neil Lončar, Marko Komljenovic, Tin Weld, David Mookherjea, Shayan Buckley, Sonia Radulaski, Marina Reitzenstein, Stephan Pingault, Benjamin Bartholomeus Machielse Mukhopadhyay, Debsuvra Akimov, Alexey Zheltikov, Aleksei Agarwal, Girish S Srinivasan, Kartik Lu, Juanjuan Tang, Hong X Jiang, Wentao McKenna, Timothy P Safavi-Naeini, Amir H Steinhauer, Stephan Elshaari, Ali W Zwiller, Val Davids, Paul S Martinez, Nicholas Gehl, Michael Chiaverini, John Mehta, Karan K Romero, Jacquiline Lingaraju, Navin B Weiner, Andrew M Peace, Daniel Cernansky, Robert Lobino, Mirko Diamanti, Eleni Luis Trigo Vidarte Camacho, Ryan M
description	Integrated photonics is at the heart of many classical technologies, from optical communications to biosensors, LIDAR, and data center fiber interconnects. There is strong evidence that these integrated technologies will play a key role in quantum systems as they grow from few-qubit prototypes to tens of thousands of qubits. The underlying laser and optical quantum technologies, with the required functionality and performance, can only be realized through the integration of these components onto quantum photonic integrated circuits (QPICs) with accompanying electronics. In the last decade, remarkable advances in quantum photonic integration and a dramatic reduction in optical losses have enabled benchtop experiments to be scaled down to prototype chips with improvements in efficiency, robustness, and key performance metrics. The reduction in size, weight, power, and improvement in stability that will be enabled by QPICs will play a key role in increasing the degree of complexity and scale in quantum demonstrations. In the next decade, with sustained research, development, and investment in the quantum photonic ecosystem (i.e. PIC-based platforms, devices and circuits, fabrication and integration processes, packaging, and testing and benchmarking), we will witness the transition from single- and few-function prototypes to the large-scale integration of multi-functional and reconfigurable QPICs that will define how information is processed, stored, transmitted, and utilized for quantum computing, communications, metrology, and sensing. This roadmap highlights the current progress in the field of integrated quantum photonics, future challenges, and advances in science and technology needed to meet these challenges.
doi_str_mv	10.48550/arxiv.2102.03323
format	Article
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There is strong evidence that these integrated technologies will play a key role in quantum systems as they grow from few-qubit prototypes to tens of thousands of qubits. The underlying laser and optical quantum technologies, with the required functionality and performance, can only be realized through the integration of these components onto quantum photonic integrated circuits (QPICs) with accompanying electronics. In the last decade, remarkable advances in quantum photonic integration and a dramatic reduction in optical losses have enabled benchtop experiments to be scaled down to prototype chips with improvements in efficiency, robustness, and key performance metrics. The reduction in size, weight, power, and improvement in stability that will be enabled by QPICs will play a key role in increasing the degree of complexity and scale in quantum demonstrations. In the next decade, with sustained research, development, and investment in the quantum photonic ecosystem (i.e. PIC-based platforms, devices and circuits, fabrication and integration processes, packaging, and testing and benchmarking), we will witness the transition from single- and few-function prototypes to the large-scale integration of multi-functional and reconfigurable QPICs that will define how information is processed, stored, transmitted, and utilized for quantum computing, communications, metrology, and sensing. This roadmap highlights the current progress in the field of integrated quantum photonics, future challenges, and advances in science and technology needed to meet these challenges.</description><identifier>EISSN: 2331-8422</identifier><identifier>DOI: 10.48550/arxiv.2102.03323</identifier><language>eng</language><publisher>Ithaca: Cornell University Library, arXiv.org</publisher><subject>Circuit design ; Circuits ; Electron tubes ; Electronic circuits ; Electronic components ; Engineers ; Integrated circuits ; Photonics ; Physics - Quantum Physics ; Quantum computing ; Qubits (quantum computing) ; Racks ; Transistors ; Tunable lasers ; Vacuum tubes</subject><ispartof>arXiv.org, 2021-09</ispartof><rights>2021. This work is published under http://creativecommons.org/licenses/by/4.0/ (the “License”). 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There is strong evidence that these integrated technologies will play a key role in quantum systems as they grow from few-qubit prototypes to tens of thousands of qubits. The underlying laser and optical quantum technologies, with the required functionality and performance, can only be realized through the integration of these components onto quantum photonic integrated circuits (QPICs) with accompanying electronics. In the last decade, remarkable advances in quantum photonic integration and a dramatic reduction in optical losses have enabled benchtop experiments to be scaled down to prototype chips with improvements in efficiency, robustness, and key performance metrics. The reduction in size, weight, power, and improvement in stability that will be enabled by QPICs will play a key role in increasing the degree of complexity and scale in quantum demonstrations. In the next decade, with sustained research, development, and investment in the quantum photonic ecosystem (i.e. PIC-based platforms, devices and circuits, fabrication and integration processes, packaging, and testing and benchmarking), we will witness the transition from single- and few-function prototypes to the large-scale integration of multi-functional and reconfigurable QPICs that will define how information is processed, stored, transmitted, and utilized for quantum computing, communications, metrology, and sensing. This roadmap highlights the current progress in the field of integrated quantum photonics, future challenges, and advances in science and technology needed to meet these challenges.</description><subject>Circuit design</subject><subject>Circuits</subject><subject>Electron tubes</subject><subject>Electronic circuits</subject><subject>Electronic components</subject><subject>Engineers</subject><subject>Integrated circuits</subject><subject>Photonics</subject><subject>Physics - Quantum Physics</subject><subject>Quantum computing</subject><subject>Qubits (quantum computing)</subject><subject>Racks</subject><subject>Transistors</subject><subject>Tunable lasers</subject><subject>Vacuum 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Eleni</creatorcontrib><creatorcontrib>Luis Trigo Vidarte</creatorcontrib><creatorcontrib>Camacho, Ryan M</creatorcontrib><collection>ProQuest SciTech Collection</collection><collection>ProQuest Technology Collection</collection><collection>Materials Science & Engineering Collection</collection><collection>ProQuest Central (Alumni Edition)</collection><collection>ProQuest Central UK/Ireland</collection><collection>ProQuest Central Essentials</collection><collection>ProQuest Central</collection><collection>Technology Collection</collection><collection>ProQuest One Community College</collection><collection>ProQuest Central Korea</collection><collection>SciTech Premium Collection</collection><collection>ProQuest Engineering Collection</collection><collection>Engineering Database</collection><collection>Access via ProQuest (Open Access)</collection><collection>ProQuest One Academic Eastern Edition (DO NOT USE)</collection><collection>ProQuest One Academic</collection><collection>ProQuest One Academic UKI Edition</collection><collection>ProQuest Central China</collection><collection>Engineering Collection</collection><collection>arXiv.org</collection><jtitle>arXiv.org</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Moody, Galan</au><au>Sorger, Volker J</au><au>Blumenthal, Daniel J</au><au>Juodawlkis, Paul W</au><au>Loh, William</au><au>Sorace-Agaskar, Cheryl</au><au>Jones, Alex E</au><au>Balram, Krishna C</au><au>Matthews, Jonathan C F</au><au>Laing, Anthony</au><au>Davanco, Marcelo</au><au>Chang, Lin</au><au>Bowers, John E</au><au>Quack, Niels</au><au>Galland, Christophe</au><au>Aharonovich, Igor</au><au>Wolff, Martin A</au><au>Schuck, Carsten</au><au>Sinclair, Neil</au><au>Lončar, Marko</au><au>Komljenovic, Tin</au><au>Weld, David</au><au>Mookherjea, Shayan</au><au>Buckley, Sonia</au><au>Radulaski, Marina</au><au>Reitzenstein, Stephan</au><au>Pingault, Benjamin</au><au>Bartholomeus Machielse</au><au>Mukhopadhyay, Debsuvra</au><au>Akimov, Alexey</au><au>Zheltikov, Aleksei</au><au>Agarwal, Girish S</au><au>Srinivasan, Kartik</au><au>Lu, Juanjuan</au><au>Tang, Hong X</au><au>Jiang, Wentao</au><au>McKenna, Timothy P</au><au>Safavi-Naeini, Amir H</au><au>Steinhauer, Stephan</au><au>Elshaari, Ali W</au><au>Zwiller, Val</au><au>Davids, Paul S</au><au>Martinez, Nicholas</au><au>Gehl, Michael</au><au>Chiaverini, John</au><au>Mehta, Karan K</au><au>Romero, Jacquiline</au><au>Lingaraju, Navin B</au><au>Weiner, Andrew M</au><au>Peace, Daniel</au><au>Cernansky, Robert</au><au>Lobino, Mirko</au><au>Diamanti, Eleni</au><au>Luis Trigo Vidarte</au><au>Camacho, Ryan M</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Roadmap on Integrated Quantum Photonics</atitle><jtitle>arXiv.org</jtitle><date>2021-09-22</date><risdate>2021</risdate><eissn>2331-8422</eissn><abstract>Integrated photonics is at the heart of many classical technologies, from optical communications to biosensors, LIDAR, and data center fiber interconnects. There is strong evidence that these integrated technologies will play a key role in quantum systems as they grow from few-qubit prototypes to tens of thousands of qubits. The underlying laser and optical quantum technologies, with the required functionality and performance, can only be realized through the integration of these components onto quantum photonic integrated circuits (QPICs) with accompanying electronics. In the last decade, remarkable advances in quantum photonic integration and a dramatic reduction in optical losses have enabled benchtop experiments to be scaled down to prototype chips with improvements in efficiency, robustness, and key performance metrics. The reduction in size, weight, power, and improvement in stability that will be enabled by QPICs will play a key role in increasing the degree of complexity and scale in quantum demonstrations. In the next decade, with sustained research, development, and investment in the quantum photonic ecosystem (i.e. PIC-based platforms, devices and circuits, fabrication and integration processes, packaging, and testing and benchmarking), we will witness the transition from single- and few-function prototypes to the large-scale integration of multi-functional and reconfigurable QPICs that will define how information is processed, stored, transmitted, and utilized for quantum computing, communications, metrology, and sensing. This roadmap highlights the current progress in the field of integrated quantum photonics, future challenges, and advances in science and technology needed to meet these challenges.</abstract><cop>Ithaca</cop><pub>Cornell University Library, arXiv.org</pub><doi>10.48550/arxiv.2102.03323</doi><oa>free_for_read</oa></addata></record>
fulltext	fulltext
identifier	EISSN: 2331-8422
ispartof	arXiv.org, 2021-09
issn	2331-8422
language	eng
recordid	cdi_arxiv_primary_2102_03323
source	Freely Accessible Journals; arXiv.org
subjects	Circuit design Circuits Electron tubes Electronic circuits Electronic components Engineers Integrated circuits Photonics Physics - Quantum Physics Quantum computing Qubits (quantum computing) Racks Transistors Tunable lasers Vacuum tubes
title	Roadmap on Integrated Quantum Photonics
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