Amazon Launches Quantum Computing Center at CalTech

<p>Amazon has launched a new facility for quantum computing at the California Institute of Technology &lpar;Caltech&rpar; with the ambitious goal of building a &&num;8220&semi;fault-tolerant&&num;8221&semi; quantum computer&period; Teams from Amazon Web Services &lpar;AWS&rpar; will focus on developing more powerful quantum computing hardware and identifying new applications for quantum technologies&period;<&sol;p>&NewLine;<p>Here are five challenges they&&num;8217&semi;ll be wrapping their heads around&colon;<&sol;p>&NewLine;<h3 class&equals;"cms-headings-h3">Making more and better qubits<&sol;h3>&NewLine;<p>Conventional computers use bits—usually represented as a value of 1<i> <&sol;i>or<i> <&sol;i>0 in code<i>—<&sol;i>as their most basic unit of information&period; A bit can be anything with two distinct states&period; For example&comma; a light that is either on or off&comma; or a door that is either open or closed&period; But quantum computers use quantum bits&comma; or &&num;8220&semi;qubits&&num;8221&semi;—usually elementary particles such as electrons or photons—to make calculations&period; Unlike bits&comma; qubits can be manipulated to exist in a quantum state known as <span class&equals;"Enhancement-inline"><span class&equals;"Enhancement-item"><a class&equals;"Link" href&equals;"https&colon;&sol;&sol;scienceexchange&period;caltech&period;edu&sol;topics&sol;quantum-science-explained&sol;quantum-superposition" target&equals;"&lowbar;blank" rel&equals;"noopener" data-cms-ai&equals;"0">superposition<&sol;a><&sol;span><&sol;span>&comma; where they are both 1 and 0 at the same time&comma; as well as all the possible states in between&period; This&comma; along with some other equally mind-bending behaviors of qubits in a quantum state&comma; allow quantum computers to perform certain calculations exponentially more efficiently than any current or future conventional computer&period; The AWS team will construct qubits from superconducting materials&comma; such as aluminum patterned into electrical circuits on silicon microchips&period; That&&num;8217&semi;s because the techniques to manufacture these are well understood&comma; making it possible to produce many more qubits&comma; in a repeatable way&comma; and at scale&period;<&sol;p>&NewLine;<div class&equals;"Enhancement" data-align-center&equals;"">&NewLine;<div class&equals;"Enhancement-item">&NewLine;<figure class&equals;"Figure"><picture><source srcset&equals;"https&colon;&sol;&sol;assets&period;aboutamazon&period;com&sol;dims4&sol;default&sol;346bda7&sol;2147483647&sol;strip&sol;true&sol;crop&sol;2000x1126&plus;0&plus;104&sol;resize&sol;1320x743&excl;&sol;format&sol;webp&sol;quality&sol;90&sol;&quest;url&equals;https&percnt;3A&percnt;2F&percnt;2Famazon-blogs-brightspot&period;s3&period;amazonaws&period;com&percnt;2F7d&percnt;2Ff5&percnt;2F6bb1c1344c01a4dc40a4eaa00246&percnt;2Fdilution-refrigerators-have-multiple-temperature-stages-to-cool-the-quantum-processor-to-temperatures-in-the-millikelvin-range-colder-than-outer-space&period;&period;jpg" type&equals;"image&sol;webp" &sol;><source srcset&equals;"https&colon;&sol;&sol;assets&period;aboutamazon&period;com&sol;dims4&sol;default&sol;d34e9c7&sol;2147483647&sol;strip&sol;true&sol;crop&sol;2000x1126&plus;0&plus;104&sol;resize&sol;1320x743&excl;&sol;quality&sol;90&sol;&quest;url&equals;https&percnt;3A&percnt;2F&percnt;2Famazon-blogs-brightspot&period;s3&period;amazonaws&period;com&percnt;2F7d&percnt;2Ff5&percnt;2F6bb1c1344c01a4dc40a4eaa00246&percnt;2Fdilution-refrigerators-have-multiple-temperature-stages-to-cool-the-quantum-processor-to-temperatures-in-the-millikelvin-range-colder-than-outer-space&period;&period;jpg" &sol;><img class&equals;"Image" src&equals;"https&colon;&sol;&sol;assets&period;aboutamazon&period;com&sol;dims4&sol;default&sol;d34e9c7&sol;2147483647&sol;strip&sol;true&sol;crop&sol;2000x1126&plus;0&plus;104&sol;resize&sol;1320x743&excl;&sol;quality&sol;90&sol;&quest;url&equals;https&percnt;3A&percnt;2F&percnt;2Famazon-blogs-brightspot&period;s3&period;amazonaws&period;com&percnt;2F7d&percnt;2Ff5&percnt;2F6bb1c1344c01a4dc40a4eaa00246&percnt;2Fdilution-refrigerators-have-multiple-temperature-stages-to-cool-the-quantum-processor-to-temperatures-in-the-millikelvin-range-colder-than-outer-space&period;&period;jpg" alt&equals;"Photo of an AWS quantum hardware engineer working on a dilution refrigerator&period; " width&equals;"1320" height&equals;"743" &sol;><&sol;picture><figcaption class&equals;"Figure-caption">An AWS quantum hardware engineer works on a dilution refrigerator&period; Dilution refrigerators can cool the quantum processor to temperatures colder than outer space&period;<&sol;figcaption><&sol;figure>&NewLine;<&sol;div>&NewLine;<&sol;div>&NewLine;<h3 class&equals;"cms-headings-h3">Keeping the noise down<&sol;h3>&NewLine;<p>The ability of qubits to exist in a quantum state is what gives quantum computers the potential to be massively more powerful than conventional computers when performing certain calculations&period; But keeping qubits in this state is—to put it mildly—a massive headache&period; Even the tiniest changes in their environment &lpar;referred to by quantum scientists as &&num;8220&semi;noise&&num;8221&semi;&rpar;&comma; such as vibrations or heat&comma; can knock them out of superposition&comma; causing them to lose information and become more error prone&period; The key to building successful quantum computers lies in controlling these errors&period; One area AWS will be investing in is material improvements to reduce noise&comma; such as superconductors with surfaces prepared one atomic layer at a time&comma; to minimize defects&period;<&sol;p>&NewLine;<h3 class&equals;"cms-headings-h3">Developing a bigger quantum computer<&sol;h3>&NewLine;<p>One of the most challenging aspects of building quantum computers is how to scale them up&period; To go beyond the realms of what&&num;8217&semi;s already possible with conventional computers&comma; they will need to be much&comma; much larger than current machines&period; Today&&num;8217&semi;s quantum computers are &&num;8220&semi;noisy&&num;8221&semi; and error prone&period; The goal for quantum researchers is to scale from a handful of noisy qubits to a machine with hundreds and then thousands of very low-noise qubits&period; The new AWS facility includes everything the teams need to push the boundaries of quantum research and development&comma; including technologies required to support bigger quantum devices&comma; such as cryogenic cooling systems to protect devices from thermal noise and nanoscale fabrication tools required to construct new forms of quantum circuits&period;<&sol;p>&NewLine;<div class&equals;"Enhancement" data-align-center&equals;"">&NewLine;<div class&equals;"Enhancement-item">&NewLine;<figure class&equals;"Figure"><picture><source srcset&equals;"https&colon;&sol;&sol;assets&period;aboutamazon&period;com&sol;dims4&sol;default&sol;ab5c07c&sol;2147483647&sol;strip&sol;true&sol;crop&sol;2000x1126&plus;0&plus;104&sol;resize&sol;1320x743&excl;&sol;format&sol;webp&sol;quality&sol;90&sol;&quest;url&equals;https&percnt;3A&percnt;2F&percnt;2Famazon-blogs-brightspot&period;s3&period;amazonaws&period;com&percnt;2F8d&percnt;2F42&percnt;2F5d4487c44203974af9a7871bab1f&percnt;2Fa-microwave-package-encloses-the-quantum-processor&period;&percnt;20The&percnt;20packaging&percnt;20is&percnt;20designed&percnt;20to&percnt;20shield&percnt;20the&percnt;20qubits&percnt;20from&percnt;20noise&percnt;20while&percnt;20enabling&percnt;20communication&percnt;20with&percnt;20the&percnt;20control&percnt;20system&lowbar;7MB&period;jpg" type&equals;"image&sol;webp" &sol;><source srcset&equals;"https&colon;&sol;&sol;assets&period;aboutamazon&period;com&sol;dims4&sol;default&sol;dd16e35&sol;2147483647&sol;strip&sol;true&sol;crop&sol;2000x1126&plus;0&plus;104&sol;resize&sol;1320x743&excl;&sol;quality&sol;90&sol;&quest;url&equals;https&percnt;3A&percnt;2F&percnt;2Famazon-blogs-brightspot&period;s3&period;amazonaws&period;com&percnt;2F8d&percnt;2F42&percnt;2F5d4487c44203974af9a7871bab1f&percnt;2Fa-microwave-package-encloses-the-quantum-processor&period;&percnt;20The&percnt;20packaging&percnt;20is&percnt;20designed&percnt;20to&percnt;20shield&percnt;20the&percnt;20qubits&percnt;20from&percnt;20noise&percnt;20while&percnt;20enabling&percnt;20communication&percnt;20with&percnt;20the&percnt;20control&percnt;20system&lowbar;7MB&period;jpg" &sol;><img class&equals;"Image" src&equals;"https&colon;&sol;&sol;assets&period;aboutamazon&period;com&sol;dims4&sol;default&sol;dd16e35&sol;2147483647&sol;strip&sol;true&sol;crop&sol;2000x1126&plus;0&plus;104&sol;resize&sol;1320x743&excl;&sol;quality&sol;90&sol;&quest;url&equals;https&percnt;3A&percnt;2F&percnt;2Famazon-blogs-brightspot&period;s3&period;amazonaws&period;com&percnt;2F8d&percnt;2F42&percnt;2F5d4487c44203974af9a7871bab1f&percnt;2Fa-microwave-package-encloses-the-quantum-processor&period;&percnt;20The&percnt;20packaging&percnt;20is&percnt;20designed&percnt;20to&percnt;20shield&percnt;20the&percnt;20qubits&percnt;20from&percnt;20noise&percnt;20while&percnt;20enabling&percnt;20communication&percnt;20with&percnt;20the&percnt;20control&percnt;20system&lowbar;7MB&period;jpg" alt&equals;"Photo of a microwave package which encloses the quantum processor&period;" width&equals;"1320" height&equals;"743" &sol;><&sol;picture><figcaption class&equals;"Figure-caption">A microwave package encloses the quantum processor&period; The packaging is designed to shield the qubits from noise while enabling communication with the control system&period;<&sol;figcaption><&sol;figure>&NewLine;<&sol;div>&NewLine;<&sol;div>&NewLine;<h3 class&equals;"cms-headings-h3">Reducing the cost of error correction<&sol;h3>&NewLine;<p>Aside from investing in innovations to reduce noise&comma; AWS will also be working on building error correction into quantum computing hardware&comma; using redundant sets of physical qubits to form so-called &&num;8220&semi;logical&&num;8221&semi; qubits&comma; which encode quantum information and can be used to detect and correct errors&period; Performing error correction in this way is typically very expensive and resource intensive&comma; due the large amount of physical hardware required to generate logical qubits&period; AWS is researching ways to reduce these costs by designing more efficient methods of implementing error correction into quantum hardware&period;<&sol;p>&NewLine;<h3 class&equals;"cms-headings-h3">Speeding up the clock<&sol;h3>&NewLine;<p>There&&num;8217&semi;s more to building a useful quantum computer than simply increasing the number of qubits&period; Another important metric is the computer&&num;8217&semi;s clock speed&comma; or the time it takes to perform &&num;8220&semi;quantum gate operations&&num;8221&semi; and do so accurately&period; &lpar;Quantum gates are essentially the building blocks of quantum circuits—the models by which quantum computers make calculations&period;&rpar; This is where superconducting qubits offer an advantage&comma; because they make it easier to speed up quantum gates&period; As AWS tries to build better qubits&comma; its ultimate measure of success will be the extent to which it can speed up the clock while reducing quantum gate errors&period;<&sol;p>&NewLine;