Physics of Everyday Phenomena 8th Edition. The Physics of Sports 1st Edition.

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Physical Science 11th Edition. ALEKS: Math Prep for College Physics ALEKS is an artificial intelligence-based system that is able to determine what a student actually understands in mathematics and then is able to determine what the student is ready to learn next knowledge states. Because it is completely individualized to each student, students are able to work at their pace and are therefore better able to master skills that once eluded them. Register for a Free Online Workshop Hosted by award-winning faculty from colleges and universities around the country, our digital workshops and webinars focus on winning classroom strategies, methods and the use of technology to drive student success in your class.

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Sign In. Anchor Links Jump to Section. College Physics It presents the strengths and weaknesses of each method so that you can choose the one that provides you with the information you need. It also reviews what each method cannot give to you, as well as how to interpret the results obtained from each method. EFTx is a graduate course on Effective Field Theory EFT , which provides a fundamental framework to describe physical systems with quantum field theory.

For residential students it is listed as 8. Past and Future of Unification via World Science U Throughout the history of physics, scientists have worked to unify many different fields into an all-encompassing description of the universe. String theorist Robbert Dijkgraaf, Director and Leon Levy Professor at the Institute for Advanced Study, discusses the connections between the very big and the infinitesimally small. Fundamental Lessons From String Theory via World Science U Cumrun Vafa, together with fellow world-renowned string theorist Andrew Strominger, developed a new way to calculate black hole entropy in the language of string theory.

Join in if you are curious but not necessarily knowledgeable about algorithms, and about the deep insights into science that you can obtain by the algorithmic approach. Mechanics: Kinematics and Dynamics Massachusetts Institute of Technology via edX Learn about kinematics and dynamics in this calculus-based physics course.

Kinematics: Describing the Motions of Spacecraft University of Colorado Boulder via Coursera This course in Kinematics covers four major topic areas: an introduction to particle kinematics, a deep dive into rigid body kinematics in two parts.

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The course ends with a look at static attitude determination, using modern algorithms to predict and execute relative orientations of bodies in space. Mechanics: Motion, Forces, Energy and Gravity, from Particles to Planets University of New South Wales via Coursera This on-demand course is recommended for senior high school and beginning university students and anyone with a curiosity about basic physics.

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The course uses rich multimedia tutorials to present the material: film clips of key experiments, animations and worked example problems, all with a friendly narrator. Mechanics: Simple Harmonic Motion Massachusetts Institute of Technology via edX Learn how to solve and understand simple harmonic motion in this calculus-based physics class. Mechanics: Rotational Dynamics Massachusetts Institute of Technology via edX Learn about rotational dynamics, rigid bodies and moment of inertia in this calculus-based physics course.

Mechanics: Momentum and Energy Massachusetts Institute of Technology via edX Learn about momentum and energy in this calculus-based physics course. Introduction to Mechanics, Part 1 Rice University via edX Learn the physics of how things move with this calculus-based course in mechanics. Control of Nonlinear Spacecraft Attitude Motion University of Colorado Boulder via Coursera This course trains you in the skills needed to program specific orientation and achieve precise aiming goals for spacecraft moving through three dimensional space.

Go To Class Next Session :. Electronic Materials and Devices Massachusetts Institute of Technology via edX Learn how electronic devices, such as diodes and transistors, are designed to exploit the electrical properties of materials. Electricity and Magnetism: Electrostatics Massachusetts Institute of Technology via edX Learn how charges interact with each other and create electric fields and electric potential landscapes in this introductory-level physics course.

Electricity and Magnetism: Magnetic Fields and Forces Massachusetts Institute of Technology via edX Learn how charges create and move in magnetic fields and how to analyze simple DC circuits in this introductory-level physics course. This introductory Electromagnetism physics course will require the use of calculus. This course provides the students a thorough understanding of the fundamentals of lasers: their unique properties, their operations and their applications. In particular the description of the solar cell operation is restricted to the ideal case In contrast this second MOOC allows a deep understanding of the properties of solar cells based on crystalline semiconductors.

Getting started in cryo-EM California Institute of Technology via Coursera This class covers the fundamental principles underlying cryo-electron microscopy cryo-EM starting with the basic anatomy of electron microscopes, an introduction to Fourier transforms, and the principles of image formation. Building upon that foundation, the class then covers the sample preparation issues, data collection strategies, and basic image processing workflows for all 3 basic modalities of modern cryo-EM: tomography, single particle analysis, and 2-D crystallography.

Learn the fundamentals as well as the latest achievements and modern applications. Statistical Molecular Thermodynamics University of Minnesota via Coursera This introductory physical chemistry course examines the connections between molecular properties and the behavior of macroscopic chemical systems. Introduction to Thermodynamics: Transferring Energy from Here to There University of Michigan via Coursera This course provides an introduction to the most powerful engineering principles you will ever learn — Thermodynamics: the science of transferring energy from one place or form to another place or form.

Understanding how energy systems work is key to understanding how to meet all these needs around the world. Because energy demands are only increasing, this course also provides the foundation for many rewarding professional careers. Thermodynamics Indian Institute of Technology Bombay via edX Introduction to basic concepts and applications of thermodynamics in mechanical engineering. The Basics of Transport Phenomena Delft University of Technology via edX Learn the basic framework to work on a broad spectrum of engineering problems concerning transfer of heat, mass and momentum.

Learn through examples of everyday processes at home, in the lab and in industry. The subject heat transfer has a wide scope and is of prime importance in almost all fields of engineering and biological systems. The course emphasizes the underlying concepts of the conduction and convection modes of heat transfer and enumerates the laws and governing equations relating to the rates of heat transfer, based on derivation from fundamentals. Atomic and Optical Physics I — Part 2: Atomic structure and atoms in external field Massachusetts Institute of Technology via edX Second part of a course in modern atomic and optical physics: the structure of atoms, and how they behave in static electromagnetic fields.

Atomic and Optical Physics I— Part 1: Resonance Massachusetts Institute of Technology via edX First part of a course in modern atomic and optical physics: the physics of resonances, a central theme in atomic physics. The student must be accepted by a member of the faculty. A lab-intensive introduction to electronic circuit design. Develops circuit intuition and debugging skills through daily hands-on lab exercises, each preceded by class discussion, with minimal use of mathematics and physics.

Moves quickly from passive circuits, to discrete transistors, then concentrates on operational amplifiers, used to make a variety of circuits including integrators, oscillators, regulators, and filters. The digital half of the course treats analog-digital interfacing, emphasizes the use of microcontrollers and programmable logic devices PLDs.

Fall W, F: pm - pm Course website. Introduction to path integrals, identical particles, many-electron theory, WKB approximation, time-dependent perturbation theory, scattering theory, and relativistic quantum mechanics. This course will review the role of symmetries in quantum mechanics. Topics include atomic and molecular symmetries, crystallographic symmetries, spontaneous symmetry breaking and phase transitions, geometrical Berry phases, topological aspects of condensed matter systems.

Mathematical basics of group theory will be taught as needed to give students an understanding of the topics covered. Introduction to elementary particle physics. Emphasis on concepts and phenomenology rather than on detailed calculational development of theories. Starts with the discovery of the electron in and ends with the theoretical motivations for the Higgs boson, and attempts to cover everything important in between.

Students will also have a brief experience of particle physics research using Atlas experiment open data. Fundamental ideas of classical mechanics including contact with modern work and applications. Topics include Lagrange's equations, the role of variational principles, symmetry and conservation laws, Hamilton's equations, Hamilton-Jacobi theory and phase space dynamics. Applications to celestial mechanics, quantum mechanics, the theory of small oscillations and classical fields, and nonlinear oscillations, including chaotic systems presented.

Students carry out three experimental projects selected from those available representing condensed matter, atomic, nuclear, and particle physics. Included are pulsed nuclear magnetic resonance with MRI , microwave spectroscopy, optical pumping, Raman scattering, scattering of laser light, nitrogen vacancies in diamond, neutron activation of radioactive isotopes, Compton scattering, relativistic mass of the electron, recoil free gamma-ray resonance, lifetime of the muon, studies of superfluid helium, positron annihilation, superconductivity, the quantum Hall effect, properties of semiconductors, and plasma physics.

The facilities of the laboratory include several computer controlled experiments as well as computers for analysis. The physics of crystalline solids and their electric, magnetic, optical, and thermal properties. Designed as a first course in solid-state physics. Topics: free electron model; Drude model; the physics of crystal binding; crystal structure and vibration phonons ; electrons in solids Bloch theorem and electronic band structures; metals and insulators; semiconductors and their applications in pn junctions and transistors ; plasmonic excitations and screening; optical transitions; solid-state lasers; magnetism, spin waves, magnetic resonance, and spin-based devices; dielectrics and ferroelectrics; superconductivity, Josephson junctions, and superconducting circuits; electronic transport in low-dimensional systems, quantum Hall effect, and resonant tunneling devices.

Standard cosmological model and inflation, scalar inflationary models, cosmological perturbation theory, brief introduction to quantum fields on cosmological backgrounds, interactions and in-in Keldysh-Schwinger perturbation theory, non-gaussianities, symmetries and cosmological Ward identities.

Basic course in nonrelativistic quantum mechanics. Introduction to relativistic quantum field theory. This course covers quantum electrodynamics. Topics include canonical quantization, Feynman diagrams, spinors, gauge invariance, path integrals, ultraviolet and infrared divergences, renormalization and applications to the quantum theory of the weak and gravitational forces. Selected advanced topics in quantum field theory, including, but not necessarily limited to: instantons, bosonization, anomalies, confinement, magnetic monopoles, large N expansions, and generalized global symmetries.

Basic principles of statistical physics and thermodynamics, with applications including: the equilibrium properties of classical and quantum gases; phase diagrams, phase transitions and critical phenomena, as illustrated by the liquid-gas transition and simple magnetic models. Time permitting, introduction to Langevin dynamics and polymer physics. This is a special topics course on quantum systems of many particles, i.

Primarily, we will be interested in condensed matter systems - eg. Mostly, we will study well defined microscopic models, involving a finite number of degrees of freedom per unit volume, such as spins on a lattice.