Gc Agarwal Physics Book Free Download
Eric
I am interested in understanding the fundamental laws of nature and ways we can test them. My research revolves around open questions in fundamental physics, such as the nature of dark matter and dark energy, and explanations for the patterns in the basic building blocks of particle physics.
Professor Agarwal received M.S. from Banaras Hindu University in 1966, and a Ph.D. from the University of Rochester in 1969. He specializes primarily in quantum optics and broadly in quantum physics. The theoretical work focuses on quantum effects in hybrid systems; quantum phase transitions and collective effects in cavities driven by squeezed light; Frohlich condensates; coupling of quantum emitters to meta materials; chiral quantum systems. The experimental effort based on super-resolution microscopy, quantum sensing and is focused towards bio-photonics applications.
I am a condensed matter theorist working on strongly correlated quantumsystems, with an emphasis on disorder and interaction driven physics, andnon-equilibrium dynamics. I am also interested in quantum control andquantum information related problems. When possible, I find it veryrewarding to collaborate with experimentalists; in the recent past, I haveworked on a wide range of problems including uncovering the properties oftopological defects in quantum Hall ferromagnets in Bismuth, phononicCherenkov radiation in graphene, and understanding the phase dynamics ofBose gases on atom chips.
I am an Assistant Professor in the Department of Physics at McGill University in Montreal, Quebec,Canada. Prior to this, I was a postdoctoral researcherat Princeton University inRavindraBhatt's group. I obtained my undergraduate degree in Electrical Engineering at the Indian Institute of Technology, Kanpur, and my PhD atHarvard University under thesupervision ofEugeneDemler.
Prof. Aggarwal is interested in precision measurements for fundamental physics. In particular, she uses techniques from Quantum Optics, atomic physics, and condensed matter physics to look for new physics in the form of dark matter candidates or gravitational waves from astrophysical, cosmological, and exotic sources.
She is a member of the LIGO (Laser Interferometer Gravitational Wave Observatory) collaboration, LSD (Levitated Sensor Detector) collaboration, and the ARIADNE (Axion Resonant InterAction DetectioN Experiment) collaboration.
She is also part of a new global initiative to build detectors for Ultra High Frequency GW detectors.
Although we endeavor to make our web sites work with a wide variety of browsers, we can only support browsers that provide sufficiently modern support for web standards. Thus, this site requires the use of reasonably up-to-date versions of Google Chrome, FireFox, Internet Explorer (IE 9 or greater), or Safari (5 or greater). If you are experiencing trouble with the web site, please try one of these alternative browsers. If you need further assistance, you may write to he...@aps.org.
Robert received his Ph.D. in theoretical high energy physics at the University of Michigan, and then worked as a postdoctoral researcher at the Canadian National Lab TRIUMF. He joined PRL in 1994. Robert was elected an APS Fellow in 2013. You can follow him on Twitter @RobertGaristo.
Alain Pumir, cole Normale Suprieure de Lyon, France and Max Planck Institute for Dynamics and Self-Organization, Germany
Laurence Ramos, University of Montpellier, France
Eric R. Weeks, Emory University, USA
Ke-Qing Xia, Southern University of Science and Technology, China
Tanniemola B. Liverpool, University of Bristol, United Kingdom
Kirsten Martens, Grenoble Alpes University and French National Centre for Scientific Research, France
Felipe Pacheco-Vzquez, Benemerita Universidad Autonoma de Puebla, Mexico
Alois Wurger, University of Bordeaux, France
Girish S. Agarwal, Fellow of the Royal Society UK,[1] (born 7 July 1946)[2] is a theoretical physicist. He is currently at the Texas A & M University with affiliations to the Departments of Biological and Agricultural Engineering, Physics and Astronomy, and the Institute for Quantum Science and Engineering.[3] Earlier he worked as Noble Foundation Chair and the Regents Professor at the Oklahoma State University.[3] He is a recognized leader in the field of quantum optics and also has made major contributions to the fields of nonlinear optics, nanophotonics and plasmonics.[4] In 2013 he published the textbook "Quantum Optics",[5] covering a wide range of recent developments in the field, which has been well received by the community.[6]
Born in Bareilly, India, Agarwal studied physics at the Gorakhpur University, Gorakhpur, India, (BSc in 1964)[3] and Banaras Hindu University in Varanasi, India, (MSc in 1966).[3] In 1969, he received his PhD from the University of Rochester, USA, followed by post-doctoral appointments at the University of Rochester, the University of Stuttgart, Germany, and The Tata Institute of Fundamental Research, Mumbai, India.[3] In 1974, at the age of 28, he published his first monograph "Quantum Statistical Theories of Spontaneous Emission and their Relation to other Approaches" at Springer.[7] This book on light-matter interaction and spontaneous decay has since been a standard reference for quantum optics researchers worldwide.
After a few years at the Tata Institute of Fundamental Research and the Institute of Science, Mumbai, India, he was appointed in 1977 full professor at the University of Hyderabad, India, where he had the major responsibility to set up the School of Physics.[3] In 1995, Girish S. Agarwal was appointed Director and Distinguished Scientist of the Physical Research Laboratory (PRL), Ahmedabad, India.[3] From 1995 - 2000 he served additionally as Honorary Professor at the Jawaharlal Nehru Centre for Advanced Scientific Research, Bangalore, India, and from 2001 - 2005 held the Einstein Centenary Research Professorship of the Indian National Science Academy. Numerous guest professorships have taken him to the major centers of optics and quantum optics throughout the world, including the University of Rochester, Texas A & M University, College Station, the University of Colorado, Boulder, the Max-Planck Institute for Quantum Optics, Garching, Germany, the Max-Planck Institute for the Science of Light, Erlangen, Germany, the Universities of Essen, Ulm, and Erlangen, Germany, the Technical University of Vienna, Austria, and the University of Manchester, UK.[3]
As a scientist he served the international optics and quantum optics community by organizing schools and symposia, e.g., at the International Center for Theoretical Physics (ICTP), Trieste, Italy, for the benefit of the scientists from third world countries. He also spearheaded the efforts of the Indian Government's Department of Science and Technology to build up the infrastructure in the Physics Departments of Indian Universities. He also has served on the editorial board of various leading journals in optics and quantum optics, including Physical Review A.
Girish S. Agarwal has received awards for his achievements in the field of optics and quantum optics.[3] This includes the Humboldt Research Award, Germany (1997),[8] the Max-Born Award of the Optical Society of America, USA (1988),[9] the Einstein Medal of the Optical and Quantum Electronics Society, USA (1994), The World Academy of Sciences Prize in Physics (1994),[10] the Shanti Swaroop Bhatnagar Award in Physical Sciences by the Government of India (1982) the Honoris causa of the University of Liege, Belgium (2007), and of the University of Hyderabad, India (2011), an Elected Fellow of The World Academy of Sciences (1997), an Elected Fellow of the Indian National Science Academy, New Delhi (1985),[11] an Elected Fellow of the Optical Society of America (1986), an Elected Fellow of the Indian Academy of Sciences, Bangalore (1981), and an Elected Fellow of the American Physical Society (1981).[12] He was invited to the Sir JC Bose Chair at the Indian Institute of Science Education and Research (IISER), Pune, India, and the JRD Tata Chair at The Tata Institute of Fundamental Research, Mumbai, India. In 2012 he was recognized by the Oklahoma State University by the "Eminent Faculty Award".
Kartiek Agarwal is a condensed matter theorist in the Material Science Division. His interests include the study of quantum materials exhibiting magnetic, superconducting, and topological properties, non-equilibrium dynamics in artificial quantum systems, and quantum information theoretic questions relating to entanglement measures, dynamics and state and Hamiltonian tomography.
Agarwal got his undergraduate degree from the Indian Institute of Technology at Kanpur, and PhD from Harvard University in 2016. He was a postdoctoral scholar at Princeton University before joining the physics department at McGill University as an assistant professor in 2019. He joined Argonne in 2024.
The site is secure.
The https:// ensures that you are connecting to the official website and that any information you provide is encrypted and transmitted securely.
Introduction: Tooth extraction is one of the most commonly performed procedures in dentistry. It is usually a traumatic procedure often resulting in immediate destruction and loss of alveolar bone and surrounding soft tissues. Various instruments have been described to perform atraumatic extractions which can prevent damage to the paradental structures. Recently developed physics forceps is one of the instruments which is claimed to perform atraumatic extractions.
Aim: The aim of the present study was to compare the efficacy of physics forceps with conventional forceps in terms of operating time, prevention of marginal bone loss & soft tissue loss, postoperative pain and postoperative complications following bilateral premolar extractions for orthodontic purpose.
Materials and methods: In this prospective split-mouth study, outcomes of the 2 groups (n = 42 premolars) requiring extraction of premolars for orthodontic treatment purpose using Physics forceps and Conventional forceps were compared. Clinical outcomes in form of time taken, loss of buccal soft tissue and buccal cortical plate based on extraction defect classification system, postoperative pain and other complication associated with extraction were recorded and compared.
b37509886e