This collection of articles and papers discusses various aspects of quantum many-body systems, quantum phase transitions, and time crystals.
1. Sondhi et al. (1997) discuss continuous quantum phase transitions in a comprehensive review.
2. Eisert et al. (2015) explore quantum many-body systems out of equilibrium.
3. Haken (2006), Keßler et al. (2019), Bu
a et al. (2019), Dogra et al. (2019), Dreon et al. (2022), and Shapere & Wilczek (2012) delve into the concepts of self-organization, emergent limit cycles, time crystal dynamics, and the fundamental principles of time crystals.
4. Sacha & Zakrzewski (2017) provide a comprehensive review of time crystals.
5. Zhang et al. (2017), Choi et al. (2017), Rovny et al. (2018), Riera-Campeny et al. (2020), Randall et al. (2021), Kyprianidis et al. (2021), Keßler et al. (2021), Mi et al. (2022), Taheri et al. (2022), and Wilczek (2012) present observations and studies on discrete time crystals in various systems, such as atom-cavity systems, disordered dipolar many-body systems, and spin-based quantum simulators.
6. Nozières (2013), Bruno (2013), Watanabe & Oshikawa (2015), Iemini et al. (2018), and Watanabe (2015) discuss the possibility, impossibility, and alternatives to time crystals, such as boundary time crystals.
7. Bakker et al. (2022), Carollo & Lesanovsky (2022), Pal et al. (2018), Cosme et al. (2019), Gambetta et al. (2019), Tuquero et al. (2022), Khasseh et al. (2019), Bu
a & Booker (2022), Ilias et al. (2022), Cabot et al. (2024), Ding et al. (2024), and Wadenpfuhl & Adams (2023) delve into the concepts of dissipative time crystals, continuous sensing, parameter estimation, and the ergodicity breaking in driven-dissipative many-body systems, with a particular focus on Rydberg atoms.
8. Carr et al. (2013), Malossi et al. (2014), Ding et al. (2020), Wu et al. (2021), Horowicz et al. (2021), Franz et al. (2024), Su et al. (2022), Medenjak et al. (2020), Guo & You (2022), Greilich et al. (2023), Else et al. (2016), Gong et al. (2018), Lazarides et al. (2020), Cabot et al. (2022), Pal et al. (2018), Cosme et al. (2019), Gambetta et al. (2019), Tuquero et al. (2022), Khasseh et al. (2019), Bu
a & Booker (2022), Ilias et al. (2022), Cabot et al. (2024), Ding et al. (2024), and Wadenpfuhl & Adams (2023) discuss various aspects of driven-dissipative many-body systems, with a focus on Rydberg atoms, and their applications in quantum computing and quantum simulation.
9. Strogatz (2018), Miller et al. (2016), Ripka et al. (2018), Li et al. (2022), Chan et al. (2015), Weller et al. (2016), Wade et al. (2018