{"id":561992,"date":"2023-06-21T13:42:49","date_gmt":"2023-06-21T17:42:49","guid":{"rendered":"https:\/\/www.rochester.edu\/newscenter\/?p=561992"},"modified":"2025-10-07T17:35:33","modified_gmt":"2025-10-07T21:35:33","slug":"quantum-computing-superconducting-circuits-qudits-561992","status":"publish","type":"post","link":"https:\/\/www.rochester.edu\/newscenter\/quantum-computing-superconducting-circuits-qudits-561992\/","title":{"rendered":"Creating superconducting circuits"},"content":{"rendered":"<figure id=\"attachment_562062\" aria-describedby=\"caption-attachment-562062\" style=\"width: 2000px\" class=\"wp-caption aligncenter\"><img loading=\"lazy\" decoding=\"async\" class=\"wp-image-562062 size-full\" src=\"https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-machiel-blok-superconducting-circuits-research-group.jpg\" alt=\"University of Rochester researchers pose for a group photo in a lab used to create superconducting circuits.\" width=\"2000\" height=\"1333\" srcset=\"https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-machiel-blok-superconducting-circuits-research-group.jpg 2000w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-machiel-blok-superconducting-circuits-research-group-630x420.jpg 630w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-machiel-blok-superconducting-circuits-research-group-768x512.jpg 768w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-machiel-blok-superconducting-circuits-research-group-1536x1024.jpg 1536w\" sizes=\"auto, (max-width: 2000px) 100vw, 2000px\" \/><figcaption id=\"caption-attachment-562062\" class=\"wp-caption-text\"><strong>CIRCUIT MAKERS:<\/strong> Physics and astronomy professor Machiel Blok (middle) and PhD students (L-R) Ray Parker, Mihirangi Medahinne, Liz Champion, and Zihao Wang, in front of the dilution refrigerator in Blok\u2019s lab. The team fabricates superconducting circuits that can be used in a variety of applications such as quantum computing. (University of Rochester photo \/ J. Adam Fenster)<\/figcaption><\/figure>\n<h2>Physicist Machiel Blok develops techniques to improve superconducting circuits, which may help create more powerful quantum computers.<\/h2>\n<p>In the quest to unlock the power of quantum computers, scientists such as <a href=\"https:\/\/www.pas.rochester.edu\/people\/faculty\/blok_machiel\/index.html\">Machiel Blok<\/a> study information processing at the infinitesimally small level of quantum mechanics.<\/p>\n<p>Blok, an assistant professor in the <a href=\"https:\/\/www.pas.rochester.edu\/index.html\">Department of Physics and Astronomy<\/a> at the <a href=\"https:\/\/www.rochester.edu\">University of Rochester<\/a>, develops superconducting circuits, a type of electronic circuit that uses materials that have little to no electrical resistance when they are at very low temperatures. When currents flow through a typical conductor, such as copper, some of the energy is lost due to resistance. In a superconductor, however, there is zero resistance, meaning it can conduct electricity without any energy loss. This property emerges due to quantum mechanical effects\u2014the behavior of particles at the atomic and subatomic levels.<\/p>\n<p>Blok is formulating new techniques to improve superconducting circuits and make quantum computers and simulators that may eventually solve problems that classical computers could never solve.<\/p>\n<div class=\"pullquote\"><span style=\"font-size: 400%;\">\u201c<\/span>Quantum algorithms are extremely sensitive to noise, and a seemingly small disturbance can lead an operation to fail. &#8230; We aim to design superconducting circuits that protect against noise in future quantum computers.\u201d<\/div>\n<p>In quantum mechanics, particles can exist in multiple states at the same time, a phenomenon known as superposition. While a regular computer consists of billions of transistors called bits, quantum computers are based on qubits. Unlike ordinary transistors, which can be either \u201c0\u201d (off) or \u201c1\u201d (on), qubits are governed by the laws of quantum mechanics and can be both \u201c0\u201d and \u201c1\u201d at the same time. Superconducting circuits can create qubits, put them into superpositions of different states, and manipulate these superpositions.<\/p>\n<p>\u201cBy carefully controlling the interactions between these qubits, researchers can execute quantum algorithms, leading to much faster computing than that conducted by classical computers,\u201d Blok says.<\/p>\n<p>Block recently received a <a href=\"https:\/\/community.apan.org\/wg\/afosr\/w\/researchareas\/12792\/young-investigator-program-yip\/\">Young Investigator Research Program award<\/a> from the <a href=\"https:\/\/community.apan.org\/wg\/afosr\/\">Air Force Office of Scientific Research<\/a> for his work in quantum information sciences. His current research explores a new way to store and transfer quantum information more efficiently in superconducting circuits using qudits instead of qubits. A qudit-based processor goes beyond binary quantum logic (\u201c0\u201d and \u201c1\u201d) and allows building blocks to have three or more logical states (\u201c0,\u201d \u201c1,\u201d \u201c2,\u201d etc.) in which to encode information. Blok\u2019s method is based on using photons\u2014tiny packets of electromagnetic radiation\u2014to create and manipulate qudits to perform computations. The method could ultimately help protect quantum information from noise\u2014unintended interactions between qudits and the environment.<\/p>\n<p>\u201cQuantum algorithms are extremely sensitive to noise, and a seemingly small disturbance can lead an operation to fail, completely ruining a quantum computation,\u201d Blok says. \u201cWe aim to design superconducting circuits that protect against noise in future quantum computers and to develop technology to make quantum computers more powerful and reliable.\u201d<\/p>\n<p><em>Photos by University photographer J. Adam Fenster.<\/em><\/p>\n<h3><strong>The making of superconducting circuits, qudit by qudit<\/strong><\/h3>\n<p><img loading=\"lazy\" decoding=\"async\" class=\"aligncenter size-full wp-image-562052\" src=\"https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-superconducting-circuits-qudits.jpg\" alt=\"Example of superconducting circuits like this one (Niobium on Silicon substrate) fabricated at the University of Rochester cleanroom (URNano).\" width=\"2000\" height=\"1333\" srcset=\"https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-superconducting-circuits-qudits.jpg 2000w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-superconducting-circuits-qudits-630x420.jpg 630w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-superconducting-circuits-qudits-768x512.jpg 768w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-superconducting-circuits-qudits-1536x1024.jpg 1536w\" sizes=\"auto, (max-width: 2000px) 100vw, 2000px\" \/><\/p>\n<p><strong>CHIP SHOT:<\/strong> Blok and the members of his lab create superconducting chips by patterning metals such as niobium or aluminum on silicon chips. They begin by fabricating a spiral resonator at the Integrated Nanosytems Center (URnano) in Goergen Hall on the River Campus in collaboration with John Nichol, an associate professor of physics. In a superconducting circuit, a spiral resonator is essentially a tightly wound wire coiled in a spiral-shaped pattern using the material\u2014in this case, niobium\u2014that will take on superconducting properties when cooled down. The spiral resonator is like a tuning fork for the electrical signals; it helps to filter and control the flow of electrical signals in a precise and efficient manner by selectively responding to and amplifying certain frequencies while minimizing other frequencies.<\/p>\n<p><img loading=\"lazy\" decoding=\"async\" class=\"aligncenter size-full wp-image-562082\" src=\"https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-blok-bluefors-dilution-refrigerator.jpg\" alt=\"BlueFors dilution refrigerator.\" width=\"2000\" height=\"1333\" srcset=\"https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-blok-bluefors-dilution-refrigerator.jpg 2000w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-blok-bluefors-dilution-refrigerator-630x420.jpg 630w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-blok-bluefors-dilution-refrigerator-768x512.jpg 768w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-blok-bluefors-dilution-refrigerator-1536x1024.jpg 1536w\" sizes=\"auto, (max-width: 2000px) 100vw, 2000px\" \/><\/p>\n<p><strong>COLD CASE:<\/strong> After the researchers have fabricated their spiral resonator, they put it in a dilution refrigerator, pictured above in Blok\u2019s lab in Bausch &amp; Lomb Hall. The dilution refrigerator cools the spiral resonator to temperatures close to absolute zero. At these temperatures, the niobium that makes up the spiral resonator becomes superconducting.<\/p>\n<p><img loading=\"lazy\" decoding=\"async\" class=\"aligncenter size-full wp-image-562092\" src=\"https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-zihao-wang-microwave-control.jpg\" alt=\"Graduate student working on a microwave control\" width=\"2000\" height=\"1333\" srcset=\"https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-zihao-wang-microwave-control.jpg 2000w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-zihao-wang-microwave-control-630x420.jpg 630w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-zihao-wang-microwave-control-768x512.jpg 768w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-zihao-wang-microwave-control-1536x1024.jpg 1536w\" sizes=\"auto, (max-width: 2000px) 100vw, 2000px\" \/><\/p>\n<p><strong>SAFE TRAVELS:<\/strong> The team measures and tests the spiral resonators using commercial microwave equipment. During this process, they send electrical signals to the spiral resonator. The signals interact with the resonator and bounce back. From the reflected signal, they can determine the resonator\u2019s properties. In essence, the researchers are analyzing the electrical components of the circuits, measuring how electricity travels through the metals, and using electrical control signals to control the photons in the metals. Pictured above is graduate student Zihao Wang.<\/p>\n<p><img loading=\"lazy\" decoding=\"async\" class=\"aligncenter size-full wp-image-562102\" src=\"https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-quantum-error-correction.jpg\" alt=\"Two graduate students at a white board discussing quantum error correction.\" width=\"2000\" height=\"1333\" srcset=\"https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-quantum-error-correction.jpg 2000w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-quantum-error-correction-630x420.jpg 630w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-quantum-error-correction-768x512.jpg 768w, https:\/\/www.rochester.edu\/newscenter\/wp-content\/uploads\/2023\/06\/inline-quantum-error-correction-1536x1024.jpg 1536w\" sizes=\"auto, (max-width: 2000px) 100vw, 2000px\" \/><\/p>\n<p><strong>TOO LEGIT QUDIT:<\/strong> The researchers, including graduate students Ray Parker and Liz Champion, then discuss and perfect the process, which could ultimately help in protecting quantum information from noise and assist in quantum error correction. The circuits have a variety of potential applications, including in quantum computing and improving the accuracy of sensors.<\/p>\n","protected":false},"excerpt":{"rendered":"<p>Rochester researchers led by Machiel Blok are formulating new techniques\u2014including one that uses qu<em>dits<\/em> instead of qu<em>bits<\/em>\u2014to improve superconducting circuits and make quantum computers that are more powerful and reliable. <a href=\"https:\/\/www.rochester.edu\/newscenter\/quantum-computing-superconducting-circuits-qudits-561992\/\">This is how they qudit >><\/a><\/p>\n","protected":false},"author":912,"featured_media":562032,"comment_status":"closed","ping_status":"closed","sticky":false,"template":"","format":"standard","meta":{"_acf_changed":false,"footnotes":""},"categories":[11556],"tags":[18662,17762,9186,16072],"class_list":["post-561992","post","type-post","status-publish","format-standard","has-post-thumbnail","hentry","category-in-photos","tag-department-of-physics-and-astronomy","tag-quantum-science","tag-research-funding","tag-school-of-arts-and-sciences"],"acf":[],"yoast_head":"<!-- This site is optimized with the Yoast SEO plugin v27.3 - https:\/\/yoast.com\/product\/yoast-seo-wordpress\/ -->\n<title>Creating superconducting circuits<\/title>\n<meta name=\"description\" content=\"University of Rochester physicist Machiel Blok develops techniques to improve superconducting circuits and make better quantum computers.\" \/>\n<meta name=\"robots\" content=\"index, follow, max-snippet:-1, max-image-preview:large, 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