BEGIN:VCALENDAR PRODID:-//AddEvent Inc//AddEvent.com v1.7//EN VERSION:2.0 BEGIN:VTIMEZONE TZID:America/New_York BEGIN:STANDARD DTSTART:20261101T010000 RRULE:FREQ=YEARLY;BYDAY=1SU;BYMONTH=11 TZOFFSETFROM:-0400 TZOFFSETTO:-0500 TZNAME:EST END:STANDARD BEGIN:DAYLIGHT DTSTART:20260308T030000 RRULE:FREQ=YEARLY;BYDAY=2SU;BYMONTH=3 TZOFFSETFROM:-0500 TZOFFSETTO:-0400 TZNAME:EDT END:DAYLIGHT END:VTIMEZONE BEGIN:VEVENT DESCRIPTION:QUANTUM CHAOS IN KICKED TOP\n\nAbstract \nQuantum-classical correspondence is of fundamental interest as it allows for computing and analysing the quantum properties with respect to their classical counterparts. This helps us study the transition from the quantum to the classical. According to the correspondence principle\, quantum mechanics should agree with classical mechanics in appropriate limits. In our first project\, we show that currently available NISQ computers can be used for versatile quantum simulations of chaotic systems. We introduce a classical-quantum hybrid approach for exploring the dynamics of the chaotic quantum kicked top (QKT) on a  universal quantum computer. The programmability of this approach allows us to experimentally explore the complete range of QKT chaoticity parameter regimes inaccessible to previous studies. Furthermore\, the number of gates in our simulation does not increase with the number of kicks\, thus making it possible to study the QKT evolution for arbitrary number of kicks without fidelity loss. Using a publicly accessible NISQ computer (IBMQ)\, we observe periodicities in the evolution of the 2-qubit QKT\, as well as signatures of chaos in the time-averaged 2-qubit entanglement. We also demonstrate a connection between entanglement and delocalization in the 2-qubit QKT\, confirming theoretical predictions. However\, the connection between classical and quantum mechanics is not straightforward\, especially in chaotic systems. The question of why a chaotic system\, in certain situations\, breaks the correspondence principle remains one of the open questions. Nevertheless\, the breaking of Quantum classical correspondence for a large system i.e.\, the large value of j (but finite)\, is surprising. It suggests that the system never behaves classically in certain situations\, irrespective of the system size. It is also worth exploring this strange behavior from an experimental point of view\, as it will decide the parameters of the experimental setup designed for studying Quantum Chaos. X-ALT-DESC;FMTTYPE=text/html:QUANTUM CHAOS IN KICKED TOP

Abstract
Quantum-classical correspondence is of fundamental interest as it allows for computing and analysing the quantum properties with respect to their classical counterparts. This helps us study the transition from the quantum to the classical. According to the correspondence principle, quantum mechanics should agree with classical mechanics in appropriate limits. In our first project, we show that currently available NISQ computers can be used for versatile quantum simulations of chaotic systems. We introduce a classical-quantum hybrid approach for exploring the dynamics of the chaotic quantum kicked top (QKT) on a  universal quantum computer. The programmability of this approach allows us to experimentally explore the complete range of QKT chaoticity parameter regimes inaccessible to previous studies. Furthermore, the number of gates in our simulation does not increase with the number of kicks, thus making it possible to study the QKT evolution for arbitrary number of kicks without fidelity loss. Using a publicly accessible NISQ computer (IBMQ), we observe periodicities in the evolution of the 2-qubit QKT, as well as signatures of chaos in the time-averaged 2-qubit entanglement. We also demonstrate a connection between entanglement and delocalization in the 2-qubit QKT, confirming theoretical predictions. However, the connection between classical and quantum mechanics is not straightforward, especially in chaotic systems. The question of why a chaotic system, in certain situations, breaks the correspondence principle remains one of the open questions. Nevertheless, the breaking of Quantum classical correspondence for a large system i.e., the large value of j (but finite), is surprising. It suggests that the system never behaves classically in certain situations, irrespective of the system size. It is also worth exploring this strange behavior from an experimental point of view, as it will decide the parameters of the experimental setup designed for studying Quantum Chaos. UID:1777899044addeventcom SUMMARY:IQC Student Seminar featuring Amit Anand DTSTART;TZID=America/New_York:20220928T120000 DTEND;TZID=America/New_York:20220928T130000 DTSTAMP:20260504T125044Z TRANSP:OPAQUE STATUS:CONFIRMED SEQUENCE:0 LOCATION:QNC 1201 X-MICROSOFT-CDO-BUSYSTATUS:BUSY BEGIN:VALARM TRIGGER:-PT30M ACTION:DISPLAY DESCRIPTION:Reminder END:VALARM END:VEVENT END:VCALENDAR