Technology and Performance Benchmarks of IQM's 20-Qubit Quantum Computer

Autor: Abdurakhimov, Leonid, Adam, Janos, Ahmad, Hasnain, Ahonen, Olli, Algaba, Manuel, Alonso, Guillermo, Bergholm, Ville, Beriwal, Rohit, Beuerle, Matthias, Bockstiegel, Clinton, Calzona, Alessio, Chan, Chun Fai, Cucurachi, Daniele, Dahl, Saga, Davletkaliyev, Rakhim, Fedorets, Olexiy, Frieiro, Alejandro Gomez, Gao, Zheming, Guldmyr, Johan, Guthrie, Andrew, Hassel, Juha, Heimonen, Hermanni, Heinsoo, Johannes, Hiltunen, Tuukka, Holland, Keiran, Hotari, Juho, Hsu, Hao, Huhtala, Antti, Hyyppä, Eric, Hämäläinen, Aleksi, Ikonen, Joni, Inel, Sinan, Janzso, David, Jaakkola, Teemu, Jenei, Mate, Jolin, Shan, Juliusson, Kristinn, Jussila, Jaakko, Khalid, Shabeeb, Kim, Seung-Goo, Koistinen, Miikka, Kokkoniemi, Roope, Komlev, Anton, Ockeloen-Korppi, Caspar, Koskinen, Otto, Kotilahti, Janne, Kuisma, Toivo, Kukushkin, Vladimir, Kumpulainen, Kari, Kuronen, Ilari, Kylmälä, Joonas, Lamponen, Niclas, Lamprich, Julia, Landra, Alessandro, Leib, Martin, Li, Tianyi, Liebermann, Per, Lintunen, Aleksi, Liu, Wei, Luus, Jürgen, Marxer, Fabian, de Griend, Arianne Meijer-van, Mitra, Kunal, Moqadam, Jalil Khatibi, Mrożek, Jakub, Mäkynen, Henrikki, Mäntylä, Janne, Naaranoja, Tiina, Nappi, Francesco, Niemi, Janne, Ortega, Lucas, Palma, Mario, Papič, Miha, Partanen, Matti, Penttilä, Jari, Plyushch, Alexander, Qiu, Wei, Rath, Aniket, Repo, Kari, Riipinen, Tomi, Ritvas, Jussi, Romero, Pedro Figueroa, Ruoho, Jarkko, Räbinä, Jukka, Saarinen, Sampo, Sagar, Indrajeet, Sargsyan, Hayk, Sarsby, Matthew, Savola, Niko, Savytskyi, Mykhailo, Selinmaa, Ville, Smirnov, Pavel, Suárez, Marco Marín, Sundström, Linus, Słupińska, Sandra, Takala, Eelis, Takmakov, Ivan, Tarasinski, Brian, Thapa, Manish, Tiainen, Jukka, Tosto, Francesca, Tuorila, Jani, Valenzuela, Carlos, Vasey, David, Vehmaanperä, Edwin, Vepsäläinen, Antti, Vienamo, Aapo, Vesanen, Panu, Välimaa, Alpo, Wesdorp, Jaap, Wurz, Nicola, Wybo, Elisabeth, Yang, Lily, Yurtalan, Ali

Quantum computing has tremendous potential to overcome some of the fundamental limitations present in classical information processing. Yet, today's technological limitations in the quality and scaling prevent exploiting its full potential. Quantum c

Externí odkaz: http://arxiv.org/abs/2408.12433

Temperature Dependent Non-linear Damping in Palladium Nano-mechanical Resonators

Autor: Abhishek Kumar, Shishram Rebari, Aaveg Aggarwal, Satyendra Prakash Pal, Ananth Venkatesan, Sagar Indrajeet, Shelender Kumar, Shyam Sundar Yadav

Advances in nano-fabrication techniques has made it feasible to observe damping phenomena beyond the linear regime in nano-mechanical systems. In this work, we report cubic non-linear damping in palladium nano-mechanical resonators. Nano-scale pallad

Externí odkaz: https://explore.openaire.eu/search/publication?articleId=doi_dedup___::7a65eaf5ade6bed261816c7e8209da9e

Tunable low-temperature dissipation scenarios in palladium nanomechanical resonators

Autor: Sagar Indrajeet, S. Rebari, Shelender Kumar, Abhishek Kumar, Satyendra Prakash Pal, Dieter Weiss, A. Venkatesan

Publikováno v: BASE-Bielefeld Academic Search Engine
Physical Review B 95 (2017): 214113. doi:10.1103/PhysRevB.95.214113
info:cnr-pdr/source/autori:Rebari S.; Kumar S.; Indrajeet S.; Kumar A.; Pal S.P.; Weiss D.; Venkatesan A./titolo:Tunable low-temperature dissipation scenarios in palladium nanomechanical resonators/doi:10.1103%2FPhysRevB.95.214113/rivista:Physical Review B/anno:2017/pagina_da:214113/pagina_a:/intervallo_pagine:214113/volume:95

We study dissipation in palladium (Pd) nanomechanical resonators at low temperatures in the linear response regime. Metallic resonators have shown characteristic features of dissipation due to tunneling two-level systems (TLS). The system described h

Externí odkaz: https://explore.openaire.eu/search/publication?articleId=doi_dedup___::29a8f7f801a1fe6560cf976664b7f9c9
https://doi.org/10.1103/physrevb.95.214113