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Kjaergaard, M.E. Schwartz, J. Braum\u00fcller, P. Krantz, J.I.-J. Wang, S. Gustavsson, and W.D. Oliver, \u201cSuperconducting qubits: Current state of play,\u201d Annu. Rev. Condens. Matter Phys., vol.11, pp.369-395, 2019. 10.1146\/annurev-conmatphys-031119-050605","DOI":"10.1146\/annurev-conmatphys-031119-050605"},{"key":"2","doi-asserted-by":"publisher","unstructured":"[2] R. Barends, J. Kelly, A. Megrant, A. Veitia, D. Sank, E. Jeffrey, T.C. White, J. Mutus, A.G. Fowler, B. Campbell, Y. Chen, Z. Chen, B. Chiaro, A. Dunsworth, C. Neill, P. O'Malley, P. Roushan, A. Vainsencher, J. Wenner, A.N. Korotkov, A.N. Cleland, and J.M. Martinis, \u201cSuperconducting quantum circuits at the surface code threshold for fault tolerance,\u201d Nature, vol.508, pp.500-503, 2014. 10.1038\/nature13171","DOI":"10.1038\/nature13171"},{"key":"3","doi-asserted-by":"publisher","unstructured":"[3] F. Arute, K. Arya, R. Babbush, D. Bacon, J.C. Bardin, R. Barends, R. Biswas, S. Boixo, F.G.S.L. Brandao, D.A. Buell, B. Burkett, Y. Chen, Z. Chen, B. Chiaro, R. Collins, W. Courtney, A. Dunsworth, E. Farhi, B. Foxen, A. Fowler, C. Gidney, M. Giustina, R. Graff, K. Guerin, S. Habegger, M.P. Harrigan, M.J. Hartmann, A. Ho, M. Hoffmann, T. Huang, T.S. Humble, S.V. Isakov, E. Jeffrey, Z. Jiang, D. Kafri, K. Kechedzhi, J. Kelly, P.V. Klimov, S. Knysh, A. Korotkov, F. Kostritsa, D. Landhuis, M. Lindmark, E. Lucero, D. Lyakh, S. Mandra, J.R. McClean, M. McEwen, A. Megrant, X. Mi, K. Michielsen, M. Mohseni, J. Mutus, O. Naaman, M. Neeley, C. Neill, M.Y. Niu, E. Ostby, A. Petukhov, J.C. Platt, C. Quintana, E.G. Rieffel, P. Roushan, N.C. Rubin, D. Sank, K.J. Satzinger, V. Smelyanskiy, K.J. Sung, M.D. Trevithick, A. Vainsencher, B. Villalonga, T. White, Z. Jamie Yao, P. Yeh, A. Zalcman, H. Neven, and J.M. Martinis, \u201cQuantum supremacy using a programmable superconducting processor,\u201d Nature vol.574, pp.505-510, 2019. 10.1038\/s41586-019-1666-5","DOI":"10.1038\/s41586-019-1666-5"},{"key":"4","doi-asserted-by":"publisher","unstructured":"[4] P. Jurcevic, A. Javadi-Abhari, L.S. Bishop, I. Lauer, D.F. Bogorin, M. Brink, L. Capelluto, O. Gunluk, T. Itoko, N. Kanazawa, A. Kandala, G.A. Keefe, K. Krsulich, W. Landers, E.P Lewandowski, D.T. McClure, G. Nannicini, A. Narasgond, H.M. Nayfeh, E. Pritchett, M.B. Rothwell, S. Srinivasan, N. Sundaresan, C. Wang, K.X. Wei, C.J. Wood, J.-B. Yau, E.J. Zhang, O.E. Dial, J.M. Chow, and J.M. Gambetta, \u201cDemonstration of quantum volume 64 on a superconducting quantum computing system,\u201d Quantum Sci. Technol., vol.6, 025020, 2021. 10.1088\/2058-9565\/abe519","DOI":"10.1088\/2058-9565\/abe519"},{"key":"5","doi-asserted-by":"publisher","unstructured":"[5] M. Gong, S. Wang, C. Zha, M.-C. Chen, H.-L. Huang, Y. Wu, Q. Zhu, Y. Zhao, S. Li, S. Guo, H. Qian, Y. Ye, F. Chen, C. Ying, J. Yu, D. Fan, D. Wu, H. Su, H. Deng, H. Rong, K. Zhang, S. Cao, J. Lin, Y. Xu, L. Sun, C. Guo, N. Li, F. Liang, V.M. Bastidas, K. Nemoto, W.J. Munro, Y.-H. Huo, C.-Y. Lu, C.-Z. Peng, X. Zhu, and J.-W. Pan, \u201cQuantum walks on a programmable two-dimensional 62-qubit superconducting processor,\u201d Science, vol.372, no.6545, pp.948-952, 2021. 10.1126\/science.abg7812","DOI":"10.1126\/science.abg7812"},{"key":"6","unstructured":"[6] J.S. Otterbach, R. Manenti, N. Alidoust, A. Bestwick, M. Block, B. Bloom, S. Caldwell, N. Didier, E. Schuyler Fried, S. Hong, P. Karalekas, C. B. Osborn, A. Papageorge, E. C. Peterson, G. Prawiroatmodjo, N. Rubin, Colm A. Ryan, D. Scarabelli, M. Scheer, E. A. Sete, P. Sivarajah, Robert S. Smith, A. Staley, N. Tezak, W. J. Zeng, A. Hudson, Blake R. Johnson, M. Reagor, M. P. da Silva, and C. Rigetti, \u201cUnsupervised machine learning on a hybrid quantum computer,\u201d arXiv:1712.05771, 2017."},{"key":"7","unstructured":"[7] C.K. Andersen, A. Remm, S. Lazar, S. Krinner, N. Lacroix, C. Hellings, A. di Paolo, F. Swiadek, G. Norris, J. Hermann, M. Gabureac, A. Blais, C. Eichler, and A. Wallraff,\u201cA device for realizing error correction with a distance-3 surface code using superconducting circuits,\u201d APS March Meeting 2021, C34.00001, 2021."},{"key":"8","unstructured":"[8] P.W. Shor, \u201cAlgorithms for quantum computation: Discrete logarithms and factoring,\u201d Proc. 35th Annu. Symp. Foundations of Computer Science, pp.124-134, 1994. 10.1109\/SFCS.1994.365700"},{"key":"9","doi-asserted-by":"crossref","unstructured":"[9] L.K. Grover, \u201cA fast quantum mechanical algorithm for database search,\u201d Proc. 28th ACM Symp. Theory of Computing, pp.212-219, July 1996. 10.1145\/237814.237866","DOI":"10.1145\/237814.237866"},{"key":"10","doi-asserted-by":"crossref","unstructured":"[10] P.W. Shor, \u201cScheme for reducing decoherence in quantum computer memory,\u201d Phys. Rev. A, vol.52, no.4, R2493, Oct. 1995. 10.1103\/PhysRevA.52.R2493","DOI":"10.1103\/PhysRevA.52.R2493"},{"key":"11","unstructured":"[11] S.B. Bravyi and A.Y. Kitaev, \u201cQuantum codes on a lattice with boundary,\u201d arXiv:quant-ph\/9811052, 1998."},{"key":"12","doi-asserted-by":"publisher","unstructured":"[12] E. Dennis, A. Kitaev, A. Landahl, and J. Preskill, \u201cTopological quantum memory,\u201d J. Math. Phys., vol.43, no.9, pp.4452-4505, Aug. 2002. 10.1063\/1.1499754","DOI":"10.1063\/1.1499754"},{"key":"13","doi-asserted-by":"publisher","unstructured":"[13] A.G. Fowler, M. Mariantoni, J.M. Martinis, and A.N. Cleland, \u201cSurface codes: Towards practical large-scale quantum computation,\u201d Phys. Rev. A, vol.86, no.3, 032324, Sept. 2012. 10.1103\/PhysRevA.86.032324","DOI":"10.1103\/PhysRevA.86.032324"},{"key":"14","doi-asserted-by":"publisher","unstructured":"[14] Y. Tomita and K.M. Svore, \u201cLow-distance surface codes under realistic quantum noise,\u201d Phys. Rev. A, vol.90, 062320, Dec. 2014. 10.1103\/PhysRevA.90.062320","DOI":"10.1103\/PhysRevA.90.062320"},{"key":"15","doi-asserted-by":"publisher","unstructured":"[15] Google Quantum AI., \u201cExponential suppression of bit or phase errors with cyclic error correction,\u201d Nature, vol.595, pp.383-387, July 2021. 10.1038\/s41586-021-03588-y","DOI":"10.1038\/s41586-021-03588-y"},{"key":"16","doi-asserted-by":"publisher","unstructured":"[16] P. Krantz, M. Kjaergaard, F. Yan, T.P. Orlando1, S. Gustavsson, and W.D. Oliver, \u201cA quantum engineer's guide to superconducting qubits,\u201d Appl. Phys. Rev., vol.6, 021318, June 2019. 10.1063\/1.5089550","DOI":"10.1063\/1.5089550"},{"key":"17","doi-asserted-by":"publisher","unstructured":"[17] J. Koch, T.M. Yu, J. Gambetta, A.A. Houck, D.I. Schuster, J. Majer, A. Blais, M.H. Devoret, S.M. Girvin, and R.J. Schoelkopf, \u201cCharge-insensitive qubit design derived from the Cooper pair box,\u201d Phys. Rev. A, vol.76, no.4, 042319, Oct. 2007. 10.1103\/PhysRevA.76.042319","DOI":"10.1103\/PhysRevA.76.042319"},{"key":"18","doi-asserted-by":"publisher","unstructured":"[18] A. Blais, R.-S. Huang, A. Wallraff, S.M. Girvin, and R.J. Schoelkopf, \u201cCavity quantum electrodynamics for superconducting electrical circuits: an architecture for quantum computation,\u201d Phys. Rev. A, vol.69, no.6, 062320, June 2004. 10.1103\/PhysRevA.69.062320","DOI":"10.1103\/PhysRevA.69.062320"},{"key":"19","doi-asserted-by":"publisher","unstructured":"[19] R. Vijay, D.H. Slichter, and I. Siddiqi, \u201cObservation of quantum jumps in a superconducting artificial atom,\u201d Phys. Rev. Lett., vol.106, 110502, March 2011. 10.1103\/PhysRevLett.106.110502","DOI":"10.1103\/PhysRevLett.106.110502"},{"key":"20","doi-asserted-by":"publisher","unstructured":"[20] C. Rigetti and M. Devoret, \u201cFully microwave-tunable universal gates in superconducting qubits with linear couplings and fixed transition frequencies,\u201d Phys. Rev. B, vol.81, no.13, 134507, April 2010. 10.1103\/PhysRevB.81.134507","DOI":"10.1103\/PhysRevB.81.134507"},{"key":"21","doi-asserted-by":"publisher","unstructured":"[21] L. DiCarlo, J. M. Chow, J.M. Gambetta, L.S. Bishop, B.R. Johnson, D.I. Schuster, J. Majer, A. Blais, L. Frunzio, S.M. Girvin, and R. J. Schoelkopf, \u201cDemonstration of two-qubit algorithms with a superconducting quantum processor,\u201d Nature, vol.460, pp.240-244, June 2009. 10.1038\/nature08121","DOI":"10.1038\/nature08121"},{"key":"22","doi-asserted-by":"publisher","unstructured":"[22] F. Yan, S. Gustavsson, A. Kamal, J. Birenbaum, A.P Sears, D. Hover, T.J. Gudmundsen, D. Rosenberg, G. Samach, S. Weber, J.L. Yoder, T.P. Orlando, J. Clarke, A.J. Kerman, and W.D. Oliver, \u201cThe flux qubit revisited to enhance coherence and reproducibility,\u201d Nature Commun., vol.7, 12964, Nov. 2016. 10.1038\/ncomms12964","DOI":"10.1038\/ncomms12964"},{"key":"23","doi-asserted-by":"publisher","unstructured":"[23] J. Majer, J.M. Chow, J.M. Gambetta, Jens Koch, B.R. Johnson, J.A. Schreier, L. Frunzio, D.I. Schuster, A.A. Houck, A. Wallraff, A. Blais, M.H. Devoret, S.M. Girvin, and R.J. Schoelkopf, \u201cCoupling superconducting qubits via a cavity bus,\u201d Nature, vol.449, pp.443-447, Sept. 2007. 10.1038\/nature06184","DOI":"10.1038\/nature06184"},{"key":"24","doi-asserted-by":"publisher","unstructured":"[24] F. Yan, P. Krantz, Y. Sung, M. Kjaergaard, D.L. Campbell, T.P. Orlando, S. Gustavsson, and W.D. Oliver, \u201cTunable Coupling Scheme for Implementing High-Fidelity Two-Qubit Gates,\u201d Phys. Rev. Applied, vol.10, no.5, 054062, Nov. 2018. 10.1103\/PhysRevApplied.10.054062","DOI":"10.1103\/PhysRevApplied.10.054062"},{"key":"25","doi-asserted-by":"publisher","unstructured":"[25] J. Krupka, J. Breeze, A. Centeno, N. Alford, T. Claussen, and L. Jensen, \u201cMeasurements of permittivity, dielectric loss tangent, and resistivity of float-zone silicon at microwave frequencies,\u201d IEEE Trans. Microw. Theory Tech., vol.54, no.11, pp.3995-4001, Nov. 2006. 10.1109\/TMTT.2006.883655","DOI":"10.1109\/TMTT.2006.883655"},{"key":"26","unstructured":"[26] M. Vahidpour, W. O'Brien, J.T. Whyland, J. Angeles, J. Marshall, D. Scarabelli, G. Crossman, K. Yadav, Y. Mohan, C. Bui, V. Rawat, R. Renzas, N. Vodrahalli, A. Bestwick, and C. Rigetti, \u201cSuperconducting through-silicon vias for quantum integrated circuits,\u201d arXiv:1708.02226, 2017."},{"key":"27","doi-asserted-by":"publisher","unstructured":"[27] D.R.W. Yost, M.E. Schwartz, J. Mallek, D. Rosenberg, C. Stull, J.L. Yoder, G. Calusine, M. Cook, R. Das, A.L. Day, E.B. Golden, D.K. Kim, A. Melville, B.M. Niedzielski, W. Woods, A.J. Kerman, and W.D. Oliver, \u201cSolid-state qubits integrated with superconducting through-silicon vias,\u201d npj Quantum Inf., vol.6, Article No. 59, 2020. 10.1038\/s41534-020-00289-8","DOI":"10.1038\/s41534-020-00289-8"},{"key":"28","unstructured":"[28] J.L. Mallek, D.-R.W. Yost, D. Rosenberg, J.L. Yoder, G. Calusine, M. Cook, R. Das, A. Day, E. Golden, D.K. Kim, J. Knecht, B.M. Niedzielski, M. Schwartz, A. Sevi, C. Stull, W. Woods, A.J. Kerman, and W.D. Oliver, \u201cFabrication of superconducting through-silicon vias,\u201d arXiv:2103.08536, 2021."},{"key":"29","doi-asserted-by":"publisher","unstructured":"[29] R. Versluis, S. Poletto, N. Khammassi, B. Tarasinski, N. Haider, D.J. Michalak, A. Bruno, K. Bertels, and L. DiCarlo, \u201cScalable quantum circuit and control for a superconducting surface code,\u201d Phys. Rev. Applied, vol.8, no.3, 034021, Sept. 2017. 10.1103\/PhysRevApplied.8.034021","DOI":"10.1103\/PhysRevApplied.8.034021"},{"key":"30","doi-asserted-by":"crossref","unstructured":"[30] P.A. Spring, S. Cao, T. Tsunoda, G. Campanaro, S.D. Fasciati, J. Wills, V. Chidambaram, B. Shteynas, M. Bakr, P. Gow, L. Carpenter, J. Gates, B. Vlastakis, and P.J. Leek, \u201cHigh coherence in a tileable 3D integrated superconducting circuit architecture,\u201d arXiv:2107.11140, 2021.","DOI":"10.1126\/sciadv.abl6698"},{"key":"31","unstructured":"[31] W. O'Brien, M. Vahidpour, J.T. Whyland, J. Angeles, J. Marshall, D. Scarabelli, G. Crossman, K. Yadav, Y. Mohan, C. Bui, V. Rawat, R. Renzas, N. Vodrahalli, A. Bestwick, and C. Rigetti, \u201cSuperconducting caps for quantum integrated circuits,\u201d arXiv:1708.02219, 2017."},{"key":"32","doi-asserted-by":"publisher","unstructured":"[32] D. Rosenberg, D. Kim, R. Das, D. Yost, S. Gustavsson, D. Hover, P. Krantz, A. Melville, L. Racz, G.O. Samach, S.J. Weber, F. Yan, J.L. Yoder, A.J. Kerman, and W.D. Oliver, \u201c3D integrated superconducting qubits,\u201d npj Quantum Inf., vol.3, Article No. 42, Oct. 2017. 10.1038\/s41534-017-0044-0","DOI":"10.1038\/s41534-017-0044-0"},{"key":"33","doi-asserted-by":"publisher","unstructured":"[33] Z. Chen, A. Megrant, J. Kelly, R. Barends, J. Bochmann, Y. Chen, B. Chiaro, A. Dunsworth, E. Jeffrey, J.Y. Mutus, P.J.J. O'Malley, C. Neill, P. Roushan, D. Sank, A. Vainsencher, J. Wenner, T.C. White, A.N. Cleland, and J.M. Martinis, \u201cFabrication and characterization of aluminum airbridges for superconducting microwave circuits,\u201d Appl. Phys. Lett., vol.104, no.5, 052602, Feb. 2014. 10.1063\/1.4863745","DOI":"10.1063\/1.4863745"},{"key":"34","doi-asserted-by":"publisher","unstructured":"[34] P.A. Spring, T. Tsunoda, B. Vlastakis, and P.J. Leek, \u201cModeling enclosures for large-scale superconducting quantum circuits,\u201d Phys. Rev. Applied, vol.14, no.2, 024061, Aug. 2020. 10.1103\/PhysRevApplied.14.024061","DOI":"10.1103\/PhysRevApplied.14.024061"},{"key":"35","doi-asserted-by":"publisher","unstructured":"[35] F. Solgun, D.P. DiVincenzo, and J.M. Gambetta, \u201cSimple impedance response formulas for the dispersive interaction Rates in the effective Hamiltonians of low anharmonicity superconducting qubits,\u201d IEEE Trans. Microw. Theory Tech., vol.67, no.3, pp.928-948, March 2019. 10.1109\/TMTT.2019.2893639","DOI":"10.1109\/TMTT.2019.2893639"},{"key":"36","doi-asserted-by":"publisher","unstructured":"[36] S. Sheldon, M. Sandberg, H. Paik, B. Abdo, J.M. Chow, M. Steffen, and J.M. Gambetta, \u201cCharacterization of hidden modes in networks of superconducting qubits,\u201d Appl. Phys. Lett., vol.111, no.22, 222601, Nov. 2017. 10.1063\/1.4990033","DOI":"10.1063\/1.4990033"},{"key":"37","doi-asserted-by":"publisher","unstructured":"[37] S. Huang, B. Lienhard, G. Calusine, A. Vepsalainen, J. Braumuller, D.K. Kim, A.J. Melville, B.M. Niedzielski, J.L. Yoder, B. Kannan, T.P. Orlando, S. Gustavsson, and W.D. Oliver, \u201cMicrowave Package Design for Superconducting Quantum Processors,\u201d PRX Quantum, vol.2, no.2, 020306, April 2021. 10.1103\/PRXQuantum.2.020306","DOI":"10.1103\/PRXQuantum.2.020306"},{"key":"38","doi-asserted-by":"publisher","unstructured":"[38] B. Foxen, J.Y. Mutus, E. Lucero, R. Graff, A. Megrant, Y. Chen, C. Quintana, B. Burkett, J. Kelly, E. Jeffrey, Y. Yang, A. Yu, K. Arya, R. Barends, Z. Chen, B. Chiaro, A. Dunsworth, A. Fowler, C. Gidney, M. Giustina, T. Huang, P. Klimov, M. Neeley, C. Neill, P. Roushan, D. Sank, A. Vainsencher, J. Wenner, T.C. White, and J.M. Martinis, \u201cQubit compatible superconducting interconnects,\u201d Quantum Sci. Technol., vol.3, no.1, 014005, Nov. 2018. 10.1088\/2058-9565\/aa94fc","DOI":"10.1088\/2058-9565\/aa94fc"},{"key":"39","unstructured":"[39] D. Rosenberg, S. Weber, D. Conway, D. Yost, J. Mallek, G. Calusine, R. Das, D. Kim, M. Schwartz, W. Woods, J.L. Yoder, and W.D. Oliver, \u201c3D integration and packaging for solid-state qubits,\u201d arXiv:1906.11146, 2019."},{"key":"40","unstructured":"[40] M. Mariantoni and A.V. Bardysheva, \u201cHigh-density qubit wiring: pin-chip bonding for fully vertical interconnects,\u201d arXiv:1810.08580, 2018."},{"key":"41","doi-asserted-by":"publisher","unstructured":"[41] N.T. Bronn, V.P. Adiga, S.B. Olivadese, X. Wu, J.M. Chow, and D.P. Pappas, \u201cHigh coherence plane breaking packaging for superconducting qubits,\u201d Quantum Sci. Technol., vol.3, no.2, 024007, Feb. 2018. 10.1088\/2058-9565\/aaa645","DOI":"10.1088\/2058-9565\/aaa645"},{"key":"42","doi-asserted-by":"publisher","unstructured":"[42] J.H. B\u00e9janin, T.G. McConkey, J.R. Rinehart, C.T. Earnest, C.R.H. McRae, D. Shiri, J.D. Bateman, Y. Rohanizadegan, B. Penava, P. Breul, S. Royak, M. Zapatka, A.G. Fowler, and M. Mariantoni, \u201cThree-dimensional wiring for extensible quantum computing: The quantum socket,\u201d Phys. Rev. Applied, vol.6, no.4, 044010, Oct. 2016. 10.1103\/PhysRevApplied.6.044010","DOI":"10.1103\/PhysRevApplied.6.044010"},{"key":"43","doi-asserted-by":"publisher","unstructured":"[43] J.B. Hertzberg, E.J. Zhang, S. Rosenblatt, E. Magesan, J.A. Smolin, J.-B. Yau, V.P. Adiga, M. Sandberg, M. Brink, J.M. Chow, and J.S. Orcutt, \u201cLaser-annealing Josephson junctions for yielding scaled-up superconducting quantum processors,\u201d arXiv:2009.00781, 2020. 10.1038\/s41534-021-00464-5","DOI":"10.1038\/s41534-021-00464-5"},{"key":"44","unstructured":"[44] E.J. Zhang, S. Srinivasan, N. Sundaresan, D.F. Bogorin, Y. Martin, J.B. Hertzberg, J. Timmerwilke, E.J. Pritchett, J.-B. Yau, C. Wang, W. Landers, E.P. Lewandowski, A. Narasgond, S. Rosenblatt, G.A. Keefe, I. Lauer, M.B. Rothwell, D.T. McClure, O.E. Dial, J.S. Orcutt, M. Brink, and J.M. Chow, \u201cHigh-fidelity superconducting quantum processors via laser-annealing of transmon qubits,\u201d arXiv:2012.08475, 2020. 10.48550\/arXiv.2012.08475"},{"key":"45","doi-asserted-by":"crossref","unstructured":"[45] A. Gold, J.P. Paquette, A. Stockklauser, M.J. Reagor, M.S. Alam, A. Bestwick, N. Didier, A. Nersisyan, F. Oruc, A. Razavi, B. Scharmann, E.A. Sete, B. Sur, D. Venturelli, C.J. Winkleblack, F. Wudarski, M. Harburn, and C. Rigetti, \u201cEntanglement across separate silicon dies in a modular superconducting qubit device,\u201d arXiv:2102.13293, 2021. 10.48550\/arXiv.2102.13293","DOI":"10.1038\/s41534-021-00484-1"},{"key":"46","doi-asserted-by":"crossref","unstructured":"[46] S. Deshpande, J.-P. Paquette, M. Vahidpour, M. Selvanayagam, R. Lion, M. Pelstring, S. Caldwell, M. Reagor, and D. Russel, \u201cIntegrating high-density microwave signalling and packaging with superconducting qubits,\u201d 2019 IEEE MTT-S International Microwave Symposium, Tu3E-6, 2019. 10.1109\/MWSYM.2019.8701125","DOI":"10.1109\/MWSYM.2019.8701125"},{"key":"47","doi-asserted-by":"publisher","unstructured":"[47] F. Lecocq, F. Quinlan, K. Cicak, J. Aumentado, S.A. Diddams, and J.D. Teufel, \u201cControl and readout of a superconducting qubit using a photonic link,\u201d Nature, vol.591, pp.575-579, March 2021. 10.1038\/s41586-021-03268-x","DOI":"10.1038\/s41586-021-03268-x"},{"key":"48","doi-asserted-by":"publisher","unstructured":"[48] E. Leonard Jr., M.A. Beck, J. Nelson, B.G. Christensen, T. Thorbeck, C. Howington, A. Opremcak, I.V. Pechenezhskiy, K. Dodge, N.P. Dupuis, M.D. Hutchings, J. Ku, F. Schlenker, J. Suttle, C. Wilen, S. Zhu, M.G. Vavilov, B.L.T. Plourde, and R. McDermott, \u201cDigital coherent control of a superconducting qubit,\u201d Phys. Rev. Applied, vol.11, no.1, 014009, Jan. 2019. 10.1103\/PhysRevApplied.11.014009","DOI":"10.1103\/PhysRevApplied.11.014009"},{"key":"49","doi-asserted-by":"publisher","unstructured":"[49] Bardin et al., IEEE J. 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