Theoretical Physics Essay
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To the outside observer, it may seem that physics is in some ways the opposite of art and that physicists must sacrifice their artistic intelligence to make way for cold rationality and logic. But nothing could be farther from the truth: Each step forward in our understanding of the universe could not have been conceived without an enormous dose of intuition and creativity.
Many successful ideas in science can be described as beautiful and very often this is a reference to the simplicity and conciseness of nature's laws. Einstein's special and general theories of relativity, which describe how space, time and gravity behave, are based on only three brief postulates. The laws of electromagnetism, which govern every aspect of how we experience the worldthrough sight, sound, smell, taste or touch, are so concise thatthey can be written on the front of a T-shirt. The Standard Model of Particle Physics, which describes all of the known particles and three of the four forces that act between them, fits on the side of a coffee mug. As we will hear from Garrett Lisi, looking for beauty in the patterns that emerge in the laws of physics can tell us about how the universe works at the most fundamental level.
Notwithstanding the significance of these recent discoveries and their agreement with predictions, our picture of the fundamental structure of the universe is far from complete: a number of big mysteries remain in both particle physics and cosmology. As we'll hear from Patricia Burchat, many of these mysteries link together the physics of the smallest elementary particles and the largest distances of the cosmos. One of the most enduring mysteries is how to reconcile a complete theory of gravity with our understanding of the fundamental particles. From Brian Greene, we'll hear about the potential of string theory to solve this problem and the possible existence of tiny, curled up, extra spatial dimensions.
As we'll hear from Aaron O'Connell, the most striking feature of quantum mechanics is that it's weird. For example, we're challenged to contemplate the possibility that a thing can be in more than one place at the same time. It's quantum mechanics, more than any other idea in fundamental physics, which forces us to question our intuition about how everyday objects behave. For the microscopic constituents of the universe, our everyday observations simply do not hold. In spite of its counter-intuitiveness, quantum mechanics has come to define our modern world through the technologies that it underpins. From the tiny switches crammed by the billions onto microchips to medical scanners and laser therapies, all rely upon the weirdness of quantum mechanics.
This series of TEDTalks discusses some of the toughest questions and the most profound ideas in fundamental physics. The concepts not only challenge us to think objectively and rationally, but also require us to put aside many of our everyday preconceptions and intuitions about how nature works. Be prepared to re-watch the talks and re-read the supporting material; trying to get your head around 13.8 billion years of the universe's history isn't something you can do in an afternoon!
is a professor in the department of applied mathematics and theoretical physics at the University of Cambridge. Along with other members of the Cambridge Supersymmetry Working Group, his research focuses on collider searches for new physics.
This book is a collection of articles dedicated to topics within the field of Standard Model physics, authored by some of the main players in both its theory and experimental development. It is edited by Luciano Maiani and Luigi Rolandi, two well-known figures in high-energy physics.
In chapter three, K Ellis reviews the evolution of our understanding of quantum chromodynamics (QCD) and deep-inelastic scattering. Among many things, he shows how the beta function depends on the strong coupling constant, αS, and explains why many perturbative calculations can be made in QCD, when the interactions take place at high-enough energies. At the hadronic scale, however, αS is too large and the perturbative expansion tool no longer works, so alternative methods have to be used. Many non-perturbative effects can be studied with the lattice QCD approach, which is addressed in chapter five. The experimental status regarding αS is reviewed in the following chapter, where G Dissertori shows the remarkable progress in measurement precision (with LHC values reaching per-cent level uncertainties and covering an unprecedented energy range), and how the data is in excellent agreement with the theoretical expectations.
Through the other chapters we can find a large diversity of topics, including a review of global fits of electroweak observables, presently aimed at probing the internal consistency of the Standard Model and constraining its possible extensions given the measured masses of the Higgs boson and of the top quark. Two chapters focus specifically on the W-boson and top-quark masses. Also discussed in detail are flavour physics, rare decays, neutrino masses and oscillations, as is the production of W and Z bosons, in particular in a chapter by M Mangano.
CERN Courier is essential reading for the international high-energy physics community. Highlighting the latest research and project developments from around the world, CERN Courier offers a unique record of the ongoing endeavour to advance our understanding of the basic laws of nature.
I am a second-year PhD student in Department of Physics and the Illinois Quantum Information Science and Technology (IQUIST) at the University of Illinois at Urbana-Champaign. I completed my B.S. dual-degree in Physics and Chemistry at Baylor University in Waco, Texas. My research is in ultracold atomic physics with the goal of investigating novel states of quantum matter for experimental approaches to quantum computing. I enjoy playing the piano and all kinds of formal writing from research-driven works to musical compositions.
Hannah Pell currently works in science publishing and as a freelance science writer. She is a former Research Assistant for the Center for History of Physics at the American Institute of Physics and an alumna of the Fulbright Program. She earned her B.S. in Physics and B.A. in Music from Lebanon Valley College and her M.A. in Music Theory from the University of Oregon. Her current research interests include science policy and communication with regards to nuclear power, large-scale high energy physics collaborations, and intersections between science and labor history. She has also been appointed to the Citizens Advisory Panel for the Three Mile Island nuclear power plant decommissioning process.
John Vastola is a Ph.D. candidate in the Department of Physics and Astronomy at Vanderbilt University. He currently uses theoretical tools from physics to better understand how individual cells regulate how many proteins and RNA of various kinds they have. More broadly, he is interested in asking and trying to answer questions about nature; for example, how do collections of apparently inanimate atoms conspire to form our friends and family?
Zhixin Wang is a Ph.D. candidate at the Department of Applied Physics and the Yale Quantum Institute at Yale University. He completed his B.S. in electrical engineering at Tsinghua University in Beijing, and his M.S. and M.Phil. in applied physics at Yale University. His research focuses on the experimental and theoretical study of superconducting quantum circuits, microwave quantum optics, and hybrid quantum systems.
Melia Bonomo is a Ph.D. candidate in applied physics at Rice University in Houston, TX. She completed her B.S. in physics with a minor in Italian at Dickinson College in Carlisle, PA and her M.S. in applied physics at Rice. Prior to graduate school, Melia spent several years teaching high school in Italy. Her current research interest is in theoretical biophysics, with a focus on applications to studying the human brain. She also enjoys investigating the history of physics and obscure scientists, particularly those with underrepresented genders.
Flavio Del Santo is a Ph.D. student in physics at the University of Vienna and Institute for Quantum Optics and Quantum Information. He completed his Bachelor in Physics and Astrophysics at the University of Florence (Italy) and his Masters in Theoretical Physics at the University of Vienna. His main research interests are the foundations of quantum mechanics, with a focus on the quantum measurement problem. He is also engaged in research activities in the history and philosophy of science.
Mathematical physics refers to the development of mathematical methods for application to problems in physics. The Journal of Mathematical Physics defines the field as "the application of mathematics to problems in physics and the development of mathematical methods suitable for such applications and for the formulation of physical theories".[1] An alternative definition would also include those mathematics that are inspired by physics (also known as physical mathematics).[2]
The rigorous, abstract and advanced reformulation of Newtonian mechanics adopting the Lagrangian mechanics and the Hamiltonian mechanics even in the presence of constraints. Both formulations are embodied in analytical mechanics and lead to understanding the deep interplay of the notions of symmetry and conserved quantities during the dynamical evolution, as embodied within the most elementary formulation of Noether's theorem. These approaches and ideas have been extended to other areas of physics as statistical mechanics, continuum mechanics, classical field theory and quantum field theory. Moreover, they have provided several examples and ideas in differential geometry (e.g. several notions in symplectic geometry and vector bundle).
Following mathematics: the theory of partial differential equation, variational calculus, Fourier analysis, potential theory, and vector analysis are perhaps most closely associated with mathematical physics. These were developed intensively from the second half of the 18th century (by, for example, D'Alembert, Euler, and Lagrange) until the 1930s. Physical applications of these developments include hydrodynamics, celestial mechanics, continuum mechanics, elasticity theory, acoustics, thermodynamics, electricity, magnetism, and aerodynamics. 2b1af7f3a8