University Physics With Modern Physics Pdf 114
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Here you may download the lab manuals for your physics course. Please bring a printed copy with you to your lab session; the TA will not have extra copies. The prelab, the first page of the lab, will be collected/submitted at the start of the lab session. TA's will also make sure that the postlabs are blank before the experiment.
Basic concepts underlying physical phenomena, including kinematics, dynamics, energy, momentum, forces found in nature, rotational motion, angular momentum, simple harmonic motion, fluids, thermodynamics and kinetic theory. Helps students understand natural phenomena and technology encountered in modern world. Prior experience in physics and calculus is not assumed. For majors and non-majors. Prerequisites: high school trigonometry and algebra. Offered fall semester. 4 credits. Levels: Graduate, Undergraduate
Introduction to physics laboratory practice and data analysis through experiments based on material from PHYS 121-122 or PHYS 131-132, or equivalent. For physics and pre-engineering majors, but useful to students in other scientific disciplines. For majors and non-majors. 4 credits. Levels: Undergraduate
The smart energy materials research stream is part of the Freshman Reseach Immerision (FRI) program which provides students with an authentic research experience in physics, chemistry and materials science research through a combination of lecture and laboratory sessions. 4 credits. Pre-Requisites: Admittance to the FRI PRogram, HARP 170, CHEM 211/MSE 211. Offered every fall semester. Course fee applies. Refer to the Schedule of Classes. Levels: Undergraduate
Introduction to physics of atoms, nuclei, elementary particles, astrophysics and cosmology. Band theory of conductors, insulators and semiconductors and devices; relativistic kinematics. Prerequisites: an average of C- or better in PHYS 121 and 122, or in 131 and 132; MATH 222. Offered fall semester. 4 credits. Levels: Graduate, Undergraduate
The smart energy materials research stream is part of the Freshman Reseach Immerision (FRI) program which provides students with an authentic research experience in physics, chemistry and materials science research through a combination of lecture and laboratory sessions. 4 credits. Pre-Requisites: Admittance to the FRI PRogram, HARP 170. Offered every fall semester. Levels: Undergraduate
Independent study by assisting in teaching a particular physics course. Various assignments directed by the course instructor, including laboratory instruction. May be repeated for a total of no more than eight credits. Credit may be earned in conjunction with a course in which a student is currently enrolled. Does not satisfy major or Harpur College Distribution requirements. Prerequisites: departmental approval and consent of instructor. Pass/Fail only. Levels: Graduate, Undergraduate
Intermediate-level treatment of ray optics using matrix methods, physical optics, image formation, coherence, interference, diffraction, Fourier optics, holography and polarization. Should be of interest to students in physics, other physical sciences and engineering. Prerequisites: PHYS 331 and differential equations. Levels: Undergraduate
Introductory treatment to selected topics in physics of solids. Simple and concrete models, using classical or elementary quantum-mechanical ideas. Prerequisite: PHYS 421. Offered spring semester. 4 credits. Levels: Undergraduate
Laboratory experiments based on material covered in electronics, analytical mechanics, electromagnetic theory and various other topics areas in physics. Restricted to MAT/MST students. Prerequisites: Modern Physics, Analytical Mechanics, Electromagnetism I. Levels: Graduate, Undergraduate
General principles of thermodynamics, kinetic theory. Introduction to statistical mechanics. Prerequisites: junior course in mechanics and senior course in quantum mechanics or modern physics. 4 Credits. Levels: Graduate, Undergraduate
Covers mathematical methods and their applications that are required for understanding physics such as quantum mechanics, electromagnetism and classical mechanics. The content is as follows: 1) differential equations (Schrodinger equations, Maxwell equation, diffusion equation, Helmholtz equation); 2) Eigen-value problems (Sturm-Liouville theory, Gram-Schmidt orthogonalization); 3) function of a complex variable (Cauchy's integral theorem, Laurent expansion); 4) integral transforms (Fourier transform, Laplace transform, Bromwich-Wagner integrals); 5) integral equations (Green function); 6) method of variations (Euler equation, Lagrange equation); 7) special functions (associated Legendre functions, Bessel functions); 8) group theory. For majors and non-majors who want to learn mathematical methods in physics such as quantum mechanics and electromagnetic theory. Prerequisites: undergraduate course in electricity and magnetism or mechanics, differential equations. Levels: Graduate, Undergraduate
Fundamental aspects of solid earth geophysics, emphasis on seismology. Basic differential equations and solutions discussed; features of earth deduced or explained; data acquisition and analysis examined. Prerequisite: mathematical methods, analytical mechanics, electricity and magnetism. Levels: Graduate, Undergraduate
Fundamental non-seismic aspects of solid earth geophysics: gravity, rotational dynamics, tides; equations of state of interior, geothermal heat flow, earth's thermal history, geomagnetic field. Observations and theory emphasized. Prerequisites: analytical mechanics, electricity and magnetism, math methods. Levels: Graduate, Undergraduate
Intermediate-level treatment of ray optics using matrix methods, physical optics, image formation, coherence, interference, diffraction, Fourier optics, holography and polarization. Should be of interest to students in physics, other physical sciences and engineering. Prerequisites: PHYS 331 and differential equations. 4 Credits. Levels: Graduate, Undergraduate
Emphasis on using computer algebra software techniques to solve a general class of problems from mainstream physics courses. Algebraic software enhances problem-solving without tedious mathematics. Its flexibility enables convenient manipulation of numerical, analytical, and graphical expressions which arise in the laboratory, in industry, and otherwise in contemporary research/technology. Prerequisite: PHYS 323 and PHYS 331. 4 Credits. Levels: Graduate, Undergraduate
Introductory treatment of selected topics in physics of solids. Simple and concrete models, using classical or elementary quantum-mechanical ideas. Prerequisite: senior-level course in quantum mechanics. 4 Credits. Levels: Graduate, Undergraduate
Content varies. May include plasma physics, reactor physics, coherent electromagnetic phenomena, information theory, particle accelerators, superfluidity, biophysics, cryophysics and upper atmosphere physics. Prerequisite: consent of instructor. Variable Credit. Levels: Graduate, Undergraduate
Individual treatment of selected topics in physics of solids. Simple and concrete models, using classical or elementary quantum-mechanical ideas. Prerequisite: senior level course in quantum mechanics. Variable Credit. Levels: Graduate, Undergraduate
Research and preparation of exposition required for MS degree in physics. Topics assigned by departmental graduate committee; may be either experimental or theoretical. Variable Credit. Levels: Graduate, Undergraduate
Foundations and techniques of quantum statistical physics; ensembles, non-equilibrium phenomena, phase transitions. Prerequisite: Senior courses in thermodynamics and kinetic theory, quantum mechanics, graduate course in analytical dynamics. 4 Credits. Levels: Graduate, Undergraduate
Introduction to quantized fields and their applications to physical systems in condensed matter, statistical mechanics, critical phenomena, and particle physics. Green functions, Feynman diagrammatic techniques, and additional topics such as path integral and renormalization group methods. Prerequisite: PHYS 524-525. 4 Credits. Levels: Graduate
This course covers modern topics in solid state physics such as superconductivity, Mott insulators, the Kondo effect, the integer and fractional quantum Hall effect, and quantum phase transitions. Methods employed will depend on selection of topics but may include second quantization, Green functions, Feynman diagrammatic techniques, path integrals and the renormalization group. Prerequisite: PHYS 572. Levels: Graduate
Stellar astronomy, neutron stars, black holes and other topics in astrophysics and cosmology. Discussion of observations, techniques and interpretations. Observations in scheduled period or in evening, as required. Notes: ASTR 114 satisfies the college science requirements. Prerequisite/corequisite: ASTR 115 must be taken in addition to ASTR 114, both on a letter-grade basis, to satisfy the General Education Laboratory Science requirement. 4 credits. Levels: Graduate, Undergraduate
Physics is the most fundamental of sciences and lies at the foundation of nearly all technical fields. All objects, from the smallest elementary particle to the universe itself, obey the laws of physics. As a physics student, you will learn how to design and run experiments, develop theories and simulate nature on computers. You will have the opportunity to work on a research project under faculty guidance. A physics degree will provide you with critical thinking, problem-solving and programming skills that are valued in a variety of careers. 2b1af7f3a8