In addition to fundamental areas of physics, the areas of astrophysics, biophysics, materials science, and nanotechnology will be included. Career opportunities for students with physics degrees will be discussed and the physics curriculum will be reviewed. The course meets weekly and is required of all physics majors and minors who are transfer students. Students who want to explore teaching careers become familiar with lesson plan development by writing, teaching and observing lessons in a local school class.
Students build and practice inquiry-based lesson design skills and become familiar with and practice classroom management in the school setting. The classroom observations and teaching represent a major field component and requires at least one two hour block of free time during the school day once a week. Students explore teaching careers, become familiar with STEM school setting through observing and discussing the school environment and by developing and teaching inquiry-based lessons. This course introduces students to the phenomena, concepts, and laws of mechanics and heat for physics majors and students in other departments.
Three classroom hours and one hour discussion per week. This course provides a phenomenological introduction to the concepts and laws of electricity and magnetism, electromagnetic waves, optics and electrical circuits for physics majors and students in other departments.
Three hours of lecture and one hour of discussion per week. Mathematical techniques specifically used in the study of mechanics, electricity, magnetism, and quantum physics are developed in the context of various physical problems. Applications to electrostatics, mechanics, and fluid dynamics are emphasized. Three hours of lecture per week. Advanced course covering single and many particle dynamics, rigid-body dynamics, and oscillations. Variational principles and Hamiltonian formulations of mechanics are covered.
Advanced course covering the rigorous development, from basic laws, of Maxwell's equations for electromagnetic fields along with applications of these equations. Topics covered are electrostatics and electrodynamics including currents, magnetic fields, motion of charged particles in fields and an introduction to electromagnetic waves. Photons and the wave nature of particles, wave mechanics, Schroedinger equation, with applications to atomic physics; and radiation; the physics of solids; elementary particles; special relativity; health physics.
Prerequisite: Consent of instructor. An independent study of special topics in physics. A paper may be required on an approved topic. Topics must be substantially different. Hours arranged. Prerequisite: Consent of department. Independent physics research projects arranged between student and instructor. This course presents a broad overview of the field of nanotechnology with an emphasis on physical phenomena involved with three main parts: Nanoscale Fabrication and Characterization nano-lithography, self-assembly and self-organization, scanning probe microscopes ; Nanomaterials and Nanostructures low-dimensional materials, graphene, carbon nanotubes, quantum dots, nano-composites, etc ; Select Applications nanoscale and molecular electronics, nano-magnetism, nano-photonics, bio-inspired nano-materials.
The goal is to lay a foundation for a research career in the rapidly growing area of nanotechnology and to enhance student's competitiveness in the job market.
Prerequisites: Consent of instructor. This is a cross-disciplinary course in two parts. Part one covers Bayesian inference as applied to data analysis in general, with a special focus on the mathematics of model-selection in the physical and life sciences. Part two concentrates specifically on the Bayesian use of log-probability i. Expect weekly empirical observation exercises, and opportunities for asynchronous as well as synchronous collaboration.
Studies of Nanoscience characterization, synthesis, modeling techniques designed for clients of these tools, as well as for technical users interested in a current overview. Check with the instructor on more specialized modules, e. Each module will cover instrumentation, current applications, weaknesses, and will involve lab visits for hands-on experience, weekly web interaction and classroom hours. This course includes the study of the properties of the various specialized electronic devices that are constructed with integrated circuits along with a study of the various circuit elements.
Prerequisite: Advanced standing with at least nine completed hours of Physics at or above the level. Physics majors are introduced to the experimental techniques used in research. A student will choose and do several special problems during the semester. Six hours laboratory per week. A study of modern optics including diffraction theory, polarization, light propagation in solids, quantum optics, and coherence. Photons and the wave nature of particles; wave mechanics, Schroedinger equation, operator and matrix formulations, and Dirac notation; applications to single particle systems, atomic physics, and spectroscopy.
Introduction to statistical mechanics, classical thermodynamics, and kinetic theory. Topics include special phenomena for research areas such as physics of waves, biophysics, nonlinear physics, geophysical fluid dynamics and the atmospheric sciences treated by methods of advanced mechanics, electromagnetism, statistical mechanics, thermodynamics and quantum mechanics.
Introduction to the application of physical principles to problems in biology. The course will cover topics such as ion transport, protein folding, molecular motors, collective dynamics and self-assembly of biological systems, x-ray crystallography and NMR, a survey of medical imaging techniques, the relation between nonlinear dynamics and electrophysiology in the heart and brain, and physics-based approaches to modeling gene networks and evolutionary dynamics. This course explains how to solve physics-based problems using computational techniques.
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Mechanics, electrodynamics, and quantum physics problems are solved by 1 numerically solving ordinary and partial differential equations, 2 using Fourier analysis, and 3 solving eigenvalue problems. Theoretical and experimental aspects of solid state physics, including one-dimensional band theory of solids; electron emission from metals and semiconductors; electrical and thermal conductivity of solids.
Dynamical theory of gases and liquids. Course covers the mathematical development of physical fluid dynamics with contemporary applications. This advanced course covers the development, from basic laws, of equations describing the many geodynamic processes underpinning geological modeling and geological data.
Topics covered are paleomagnetism, plate tectonics, viscoelastic media, heat transfer, gravity, fluid mechanics, rheology, faulting, and geochronology. An introduction to Einstein's general theory of relativity. Topics will include special relativity in the formalism of Minkowski's four dimensional space-time, Principle of Equivalence, metric description of curved space, geodesic equation, Einstein Field Equation, black holes, and cosmology.
Department of Physics
An independent study of special topics in physics for senior undergraduates or graduate students. Prerequisites: Graduate standing in physics or consent of instructor. Advanced studies of Nanoscience characterization, synthesis, and modeling techniques designed for clients of these tools, as well as for technical users interested in a current overview.
Each module will cover instrumentation, current applications, and weaknesses and will involve lab visits for hands-on experience, weekly web interaction and classroom hours. Dynamical systems; theory of oscillations; introduction to bifurcation theory and chaos in dissipative systems with applications in physics and biology; introduction to stochastic processes with applications in physics, chemistry and biology; dynamics of nonlinear systems perturbed by noise; noise-induced phase transitions; linear and nonlinear time series analysis.
Graduate-level introduction to the application of physical principles to problems in biology. The course will cover such topics as ion transport, protein folding, molecular motors, collective dynamics and self-assembly of biological systems, x-ray crystallography and NMR, a survey of medical imaging techniques, the relation between nonlinear dynamics and electrophysiology in the heart and the brain, and physics-based approaches to modeling gene networks and evolutionary dynamics.
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Nuclear phenomenology and models; high energy particle accelerators and detectors; phenomenology of strong, electromagnetic and weak interactions; symmetry principles; quark compositions of strongly interacting baryons and mesons; gauge theories and the standard model of particle interactions; grand unification.
Topics will include special relativity in the formalism of Minkowski's four dimensional space-time, Principle of Equivalence, geodesic equation, Einstein Field Equation, black holes, and cosmology. Differential geometry from metric description to Riemann curvature tensor will be studied.
Prerequisites: Graduate standing in physics or consent of instructor A course covering mathematical techniques as applied in advanced theoretical physics including generalized vector spaces and their dual spaces, linear operators and functionals, generalized functions, spectral decomposition of operators, tensor analysis, and complex variables. Boundary value problems; Strum-Liouville theory and orthogonal functions; Green's function techniques; and introduction to group theory with emphasis on representations of Lie Algebras. Thesis work under the supervision of a faculty member.
The course is designed for those students intending to present a thesis as part of their M. This course transfers to the Cooperative Ph.
Must have faculty mentor and approval of Department Chairperson. A study of special topics in physics for graduate students. This course is designed to give the department an opportunity to test a new course. Classical mechanics, methods of Newton, Lagrange, and Hamilton applied to motion of particles and rigid bodies, elasticity, hydrodynamics.
Prerequisite: Approval of Department Chair. Discussion of current topics. A rigorous development of the fundamentals of electromagnetic fields and waves. Electrostatics, magnetostatics, Maxwell's equations, Green's functions, boundary value problems, multipoles, conservation laws.
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A study of statistical ensembles; Maxwell-Boltzmann, Fermi-Dirac and Einstein-Bose distribution laws, application to some physical systems. Applications of time-dependent Maxwell's equations to such topics as plasmas, wave guides, cavities, radiation: fields of simple systems and multiples. All papers to be sat the end of the second year of the course. This includes two theory papers assessing topics across the two years of the course, using a mixture of multiple-choice and written responses the majority of marks for the latter and one paper testing practical knowledge, including practical design, analysis of specimen data and links to theory.
In addition to this, a certificate of practical competence is awarded, dependent upon performance within specified practical work. Examining Board — AQA. In addition, standard A level entry requirements apply. Statistics is not a suitable course to study with Physics; instead students should choose Mathematics. It also directly links to careers within design, the armed forces and sports science.
The skills it develops are also valued within a wide range of other careers, such as the financial industry. Most students go to university and study a range of subjects. Come along to one of our free college open days and see what courses and options we have to offer you.
Book your place today! She studied A level French, German and…. Why study Physics? Physics is the most fundamental of the sciences, with its ultimate goal being to understand any and all aspects of how our universe, from the apparently simple e. This course is for those who want to know just how and why the natural world works as it does, and covers a wide range of physics topics from the tiniest scale of sub-atomic particles to the evolution of the cosmos.
The course aims to develop an interest and enthusiasm for the subject along with the full skill-set needed to be successful within it practicing Physics requires a high level of mathematical, communication and thinking skills. We have a dedicated team of A Level Physics subject specialists who deliver high quality lessons. Teachers are also examiners for AQA so know how to embed exam skills into your learning. We have well equipped subject specific laboratories, so all lessons take place in a stimulating environment.
Tests are set at the end of each topic area to allow students to assess their level of understanding within it. We are furnished with excellent lab equipment, so your practical lessons are fully hands-on and minds-on.