El grupo de Termodinámica y Computación Cuántica les invita al siguiente seminario Fecha: Viernes 15 de Marzo Hora: 11:00 am Lugar: Laboratorio de Física Computacional, Dept de Electromagnetismo y Física de al Materia, Planta Baja, Facultad de Ciencias (junto al péndulo gigante) Ponente: Alvaro Tejero (Departamento de Electromagnetismo y Física de la Materia, Universidad de Granada) Titulo: Lectures on Quantum Thermodynamics II Resumen: Quantum thermodynamics arises when extending the ideas from classical thermodynamics to the microscopic, i.e., quantum, regime. In this course, we will address the fundamentals of the theory focusing on the laws of quantum thermodynamics. We will also present the main practical applications of this theory, such as quantum thermal machines and batteries, and point out the main conceptual issues when dealing with quantities such as heat, work, or entropy. Please note: This is a graduate-level course. Attendees are expected to have a minimum understanding of thermodynamics and quantum theory. While familiarity with Master Equation techniques is advisable (see Ref. [1]), a general overview will be provided at the beginning of the course. Structure: 1. Introduction and historical motivation 2. Previous key concepts 3. Laws of Quantum Thermodynamics 4. Entropy production, Quantum Information and Thermodynamics 5. Applications: Quantum thermal engines and batteries [1] D. Manzano, A short introduction to the Lindblad master equation, AIP Advances 10, 025106 (2020). (https://arxiv.org/abs/1906.04478) [2] P. Strasberg, Quantum Stochastic Thermodynamics: Foundations and Selected Applications. Oxford University Press (2022) [3] S. Deffner and S. Campbell, Quantum Thermodynamics: An introduction to the thermodynamics of quantum information, Morgan & Claypool Publishers (2019). (https://arxiv.org/abs/1907.01596) [4] F. Binder et al. (eds.), Thermodynamics in the quantum regime. Springer (2018) [5] S. Vinjanampathy and J. Anders, Quantum Thermodynamics, Contemporary Physics, 57, 545 (2016) (https://arxiv.org/abs/1508.06099) [6] G. Landi and M. Paternostro, Irreversible entropy production, from quantum to classical, Rev. Mod. Phys. 93, 035008 (2021) (https://arxiv.org/abs/2009.07668) [7] S. Bhattacharjee and A. Dutta, Quantum thermal machines and batteries, Eur. Phys. J. B 94, 239 (2021) (https://arxiv.org/abs/2008.07889) [8] N. Myers, O. Abah and S. Deffner, Quantum thermodynamic devices: from theoretical proposals to experimental reality, AVS Quantum Sci. 4, 027101 (2022) (https://arxiv.org/abs/2201.01740) El seminario es accesible para los estudiantes de grado con conocimientos basicos en Termodynámica y Información Cuántica , a los que recomendamos encarecidamente que asistan. Para aquellos que no puedan asistir, también hemos configurado una reunión de Google donde el seminario se transmitirá en vivo. https://meet.google.com/pfu-awyh-hmz También os recordamos a todos la página web del Seminario de Grupos, https://ic1.ugr.es/eventos/wp/qjc/ donde se publicarán anuncios pasados, presentes y futuros. Nos vemos a todos allí DJM -------------------------------------------------------------------------------------------------- Dear all The Quantum Thermodynamics and Computation group cordially invites you to the following seminar Date: Friday March 15th Time: 11:00 am Location: Computational Physics Laboratory, Department of Electromagnetism and Condensed Mater, Ground Floor, Faculty of Science (next to the giant pendulum) Speaker: Alvaro Tejero (Department of electromagnetism and Condensed Matter, University of Granada ) Title: Lectures on Quantum Thermodynamics II Abstract: Quantum thermodynamics arises when extending the ideas from classical thermodynamics to the microscopic, i.e., quantum, regime. In this course, we will address the fundamentals of the theory focusing on the laws of quantum thermodynamics. We will also present the main practical applications of this theory, such as quantum thermal machines and batteries, and point out the main conceptual issues when dealing with quantities such as heat, work, or entropy. Please note: This is a graduate-level course. Attendees are expected to have a minimum understanding of thermodynamics and quantum theory. While familiarity with Master Equation techniques is advisable (see Ref. [1]), a general overview will be provided at the beginning of the course. Structure: 1. Introduction and historical motivation 2. Previous key concepts 3. Laws of Quantum Thermodynamics 4. Entropy production, Quantum Information and Thermodynamics 5. Applications: Quantum thermal engines and batteries [1] D. Manzano, A short introduction to the Lindblad master equation, AIP Advances 10, 025106 (2020). (https://arxiv.org/abs/1906.04478) [2] P. Strasberg, Quantum Stochastic Thermodynamics: Foundations and Selected Applications. Oxford University Press (2022) [3] S. Deffner and S. Campbell, Quantum Thermodynamics: An introduction to the thermodynamics of quantum information, Morgan & Claypool Publishers (2019). (https://arxiv.org/abs/1907.01596) [4] F. Binder et al. (eds.), Thermodynamics in the quantum regime. Springer (2018) [5] S. Vinjanampathy and J. Anders, Quantum Thermodynamics, Contemporary Physics, 57, 545 (2016) (https://arxiv.org/abs/1508.06099) [6] G. Landi and M. Paternostro, Irreversible entropy production, from quantum to classical, Rev. Mod. Phys. 93, 035008 (2021) (https://arxiv.org/abs/2009.07668) [7] S. Bhattacharjee and A. Dutta, Quantum thermal machines and batteries, Eur. Phys. J. B 94, 239 (2021) (https://arxiv.org/abs/2008.07889) [8] N. Myers, O. Abah and S. Deffner, Quantum thermodynamic devices: from theoretical proposals to experimental reality, AVS Quantum Sci. 4, 027101 (2022) (https://arxiv.org/abs/2201.01740) The seminar is accessible to undergraduate students with a basic knowledge in Thermodynamics and Quantum Information, whom we strongly encourage to attend. For those of you unable to attend the seminar, we have set-up the following google meet link for the upcoming seminar. https://meet.google.com/pfu-awyh-hmz We would also like to bring to your attention the groups seminar page https://ic1.ugr.es/eventos/wp/qjc/ where you can find relevant material and information about past, present, and future seminars. See you all there DJM.--------------------------------------------------------- Dr. Michalis Skotiniotis Grupo de Termodinámica y Información Cuántica. Departamento de Electromagnetismo y Física de la Materia. Instituto Carlos I de Física Teórica y Computacional. Facultad de Ciencias, Av. Fuentenueva s/n Universidad de Granada Granada, 18071 Spain Email: mskotiniotis@onsager.ugr.es ---------------------------------------------------------