Lecture Videos

Quantum Computation and Quantum Information Lecture 6: Partial Measurements and Spooky Action at a Distance Carnegie Mellon Course 15-859BB, Fall 2018 https://www.cs.cmu.edu/~odonnell/quan... Course discussion board at https://www.diderot.one Email cmuquantum2018@gmail.com for access Weekly work: http://www.cs.cmu.edu/~odonnell/quant... Taught by Ryan O'Donnell Filmed by Dave A. for Panopto (http://www.panopto.com/) Thumbnail image by Eels and Ticha Sethapakdi

Quantum Computation and Quantum Information Lecture 5.5: Multiplying By A Global Phase Doesn't Make A Difference Carnegie Mellon Course 15-859BB, Fall 2018 https://www.cs.cmu.edu/~odonnell/quan... Course discussion board at https://www.diderot.one Email cmuquantum2018@gmail.com for access Weekly work: http://www.cs.cmu.edu/~odonnell/quant... Taught by Ryan O'Donnell Thumbnail image by Eels and Ticha Sethapakdi

Quantum Computation and Quantum Information Lecture 5: Multi-Qubit Systems Carnegie Mellon Course 15-859BB, Fall 2018 https://www.cs.cmu.edu/~odonnell/quan... Course discussion board at https://www.diderot.one Email cmuquantum2018@gmail.com for access Weekly work: http://www.cs.cmu.edu/~odonnell/quant... Taught by Ryan O'Donnell Filmed by Dave A. for Panopto (http://www.panopto.com/) Thumbnail image by Eels and Ticha Sethapakdi

Quantum Computation and Quantum Information Lecture 4.5: Discriminating Two Qubits Carnegie Mellon Course 15-859BB, Fall 2018 https://www.cs.cmu.edu/~odonnell/quan... Course discussion board at https://www.diderot.one Email cmuquantum2018@gmail.com for access Weekly work: http://www.cs.cmu.edu/~odonnell/quant... Taught by Ryan O'Donnell Thumbnail image by Eels and Ticha Sethapakdi

Quantum Computation and Quantum Information Lecture 4: Unitary Transformations and the Elitzur--Vaidman Bomb Carnegie Mellon Course 15-859BB, Fall 2018 https://www.cs.cmu.edu/~odonnell/quan... Course discussion board at https://www.diderot.one Email cmuquantum2018@gmail.com for access Weekly work: http://www.cs.cmu.edu/~odonnell/quant... Taught by Ryan O'Donnell Filmed by Dave A. for Panopto (http://www.panopto.com/) Thumbnail image by Eels and Ticha Sethapakdi

Quantum Computation and Quantum Information Lecture 3: Understanding and Measuring One Qubit Carnegie Mellon Course 15-859BB, Fall 2018 https://www.cs.cmu.edu/~odonnell/quan... Course discussion board at https://www.diderot.one Email cmuquantum2018@gmail.com for access Weekly work: http://www.cs.cmu.edu/~odonnell/quant... Taught by Ryan O'Donnell Filmed by Dave A. for Panopto (http://www.panopto.com/) Thumbnail image by Eels and Ticha Sethapakdi

Quantum Computation and Quantum Information Lecture 2: Rotate, Compute, Rotate Carnegie Mellon Course 15-859BB, Fall 2018 https://www.cs.cmu.edu/~odonnell/quan... Course discussion board at https://www.diderot.one Email cmuquantum2018@gmail.com for access Weekly work: http://www.cs.cmu.edu/~odonnell/quant... Taught by Ryan O'Donnell Filmed by Dave A. for Panopto (http://www.panopto.com/) Thumbnail image by Eels and Ticha Sethapakdi

Quantum Computation and Quantum Information Lecture 1: 10^500 Parallel Universes Carnegie Mellon Course 15-859BB, Fall 2018 https://www.cs.cmu.edu/~odonnell/quan... Course discussion board at https://www.diderot.one Email cmuquantum2018@gmail.com for access Weekly work: http://www.cs.cmu.edu/~odonnell/quant... Taught by Ryan O'Donnell Filmed by Dave A. for Panopto (http://www.panopto.com/) Thumbnail image by Eels and Ticha Sethapakdi

The laws of thermodynamics are fundamental laws of nature that classify energy changes for macroscopic systems as work performed by external driving and heat exchanged with the environment. In the past decades, these principles have been successfully extended to the level of classical trajectories of microscopic systems to account for thermal fluctuations. In particular, experimentally tested generalizations of the second law, known as fluctuation theorems, quantify the occurrence of negative entropy production. The extension of thermodynamics to include quantum fluctuations faces unique challenges such as the proper identification of heat and work and clarification of the role of quantum coherence. I will present experiments that allow us to track heat and work along single quantum trajectories of a superconducting qubit evolving under continuous unitary evolution and measurement. We are able to verify the first law of thermodynamics in that the measured heat and work sum to the total energy change of the quantum system.  We then verify the second law of thermodynamics in the form of the Jarzynski equality by employing a novel quantum feedback loop that cancels the heat exchanged at each point in time with additional work.  Our results successfully generalize stochastic thermodynamics to the quantum regime, paving the way for future experimental and theoretical investigations of quantum information and thermodynamics.

Geometrical effects influencing the measured spin coherence and quantum phase coherence in mesoscopic structures were characterized by low-temperature spin-dependent quantum transport experiments.  The findings are of possible relevance for the design of devices for quantum technologies, and have foundational aspects as well.  The materials studied have strong spin-orbit interaction and are heterostructures of InSb, InAs, or InGaAs, and the semimetal Bi with its surface states. The materials were patterned into mesoscopic stadia, narrow channels or quantum interferometers, of typical size ~ 1 micron, comparable to the spin and quantum phase coherence lengths.  Aharonov-Bohm experiments, antilocalization, and universal conductance fluctuations were used to quantify the spin- and quantum phase coherence lengths.  Using geometrical constraints on the accumulation of quantum geometric phases, the work shows a correspondence, in a diffusive transport regime, between mesoscopic dephasing effects due to time-reversal symmetry breaking by magnetic fields, and spin decoherence due to spin-orbit interaction (Aharonov-Bohm / Aharonov-Casher correspondence).  The work also reveals device-geometrical influences on quantum phase coherence from coupling to the classical environment and geometrical effects of electron-electron interactions.

Pages