Physics and Astronomy

Conceptual description of our fascinating universe: early astronomy, Newtonian synthesis, Earth, Moon, planets, asteroids, comets, the sun, our solar system, stars, black holes, galaxies, dark matter, dark energy and cosmological mysteries.Meets New Mexico Lower-Division General Education Common Core Curriculum Area III: Science (NMCCN 1114).

Intended as an adjunct to ASTR 101, this course deals with elementary techniques in astronomical observations. Two hours lab. Meets New Mexico Lower-Division General Education Common Core Curriculum Area III: Science (NMCCN 1114).

Pre- or corequisite: ASTR 101

Designed as a follow-up course to 101. This course will focus on one topic in astronomy for an in-depth investigation of its core concepts and implications. May be repeated, but topics must be substantially different from semester to semester.

Prerequisite: 101

{Offered upon demand.}

Concepts of astronomy with emphasis on the solar system.

Prerequisite: MATH 123 or Compass Trig Test =>60.  Pre- or corequisite: (MATH 150 or 162) and any physics course numbered 150 or higher.

{Fall}

Observations of the moon, planets and stars.  Three hours lab.

Pre- or corequisite: 270

{Fall}

Stellar astronomy, the galaxy, extra-galactic systems, cosmology.

Prerequisite: MATH 123 or Compass Trig Test =>60.  Pre- or corequisite: (MATH 150 or 162) and any physics course numbered 150 or higher.

{Spring}

Observations of the moon, planets and stars. Three hours lab.

Pre- or corequisite: 271

{Spring}

Gravitation, radiation, relativity, stellar atmospheres, structure, and evolution.

Prerequisite: PHYC 330

{Fall}

Applications of advanced astrophysical concepts to the interstellar medium, star formation, the Milky Way, external galaxies, and cosmology.

Prerequisite: 421

{Spring}

Single dish and aperture synthesis radio observations; emission processes at radio wavelengths: synchrotron radiation, thermal bremsstrahlung.

Prerequisite: PHYC 330

{Alternate Springs}

Distribution, properties and interactions of galaxies and quasars; large scale clusterings of matter, formation and evolution of the universe; physical cosmology.

{Offered upon demand}

Principles of optics and quantum physics applied to modern astronomical instrumentation (over a wide range of electromagnetic wavelengths), data acquisition and processing.

{Offered upon demand}

Planetary physics; planetary investigation using space vehicles; optical properties of planetary atmospheres.

{Offered upon demand}

(Also offered as PHYC 456)

Independent studies course for students seeking departmental honors.

(Also offered as PHYC 536)

Astrophysical problems illustrating E&M and classical/statistical mechanics: expansion of the universe; dark matter; big-bang nucleosynthesis; stellar interiors; neutron stars; supernovae. May be repeated when topics are different.

{Alternate Falls}

Astrophysical problems as illustrations of quantum mechanics: atoms; molecules; spectral lines; ionized regions surrounding stars; centers of active galaxies; Lyman-alpha forest. May be repeated when topics are different.

Prerequisite: PHYC 521.

{Alternate Springs}

Designed to introduce non-science majors to basic concepts, laws and skills in physics, in various applications to ordinary life. Energy, momentum, force, wave phenomena, electric charge and light are discussed; also basic properties of gravitational, electromagnetic and nuclear forces. Selections from relativity, quantum theory, atoms and molecules will be included. See PHYC 102L for an optional laboratory. Meets New Mexico Lower-Division General Education Common Core Curriculum Area III: Science.

Students involve themselves in experiments and projects showing basic concepts related to the atom, the environment and the universe. Meets New Mexico Lower-Division General Education Common Core Curriculum Area III: Science.  Two hours lab.

Pre- or corequisite: 102

Designed to introduce non-science majors to basic concepts, laws and skills in classical and quantum physics as a basis to discuss the interrelationships of society and physics. Examples where energy, momentum, special relativity, thermal physics, quantum and nuclear physics have important roles are discussed; these could include meteorology, aviation weather, fission and fusion reactors, science policy and ethics, alternative energy sources.

{Spring}

Designed to introduce non-science majors to basic concepts, laws and skills in physics, in the context of a study of sound, acoustics and music. Energy and force involved with the physical nature of sound waves; application to harmonics, tone quality, pitch. Sound production, propagation, detection and perception are demonstrated and illustrated by many different musical instruments, building acoustics and the behavior of the voice and the ear. See PHYC 108L for an optional laboratory.

{Spring}

Student involvement in experiments and demonstrations with sound waves, measurements of properties of musical instruments and electronic equipment measuring musical and acoustic properties. Two hours lab.

Pre- or corequisite: 108

{Spring}

Preparatory course to review skills needed for PHYC 151/160. Reviews math skills (vectors, trigonometry, word problems, solving equations, etc.) through applications of physics principles to examples such as cell phones, musical instruments, CD players, driving, tools, projectiles, athletics, and electrical circuits.

Prerequisite: MATH 121 or SAT=>570 or ACT=>25.

{Second half of Fall and Spring}

Mechanics, sound, heat, fluid, waves. The sequence (151, 151L, 152, 152L) is required of pre-medical, pre-dental, and pre-optometry students. Only 151 and 152 are required of pharmacy students. Meets New Mexico Lower-Division General Education Common Core Curriculum Area III: Science (NMCCN 1114).

Prerequisite: (MATH 123 or Compass Trig Test=>60) and (MATH 150 or MATH 162 or MATH 180 or ACT>27 or SAT>630).

{Summer, Fall, Spring}

Mechanics, sound, heat. Meets New Mexico Lower-Division General Education Common Core Curriculum Area III: Science (NMCCN 1114). Three hours lab.

Pre- or corequisite: 151

Electricity, magnetism, optics. Meets New Mexico Lower-Division General Education Common Core Curriculum Area III: Science (NMCCN 1124).

Prerequisite: 151

Electricity, magnetism, optics. Meets New Mexico Lower-Division General Education Common Core Curriculum Area III: Science (NMCCN 1124). Three hours lab.

Pre- or corequisite: 152

Problem solving and demonstrations related to 151.

Corequisite: 151

Offered on a CR/NC basis only.

Problem solving and demonstrations related to 152.

Corequisite: 152

Offered on a CR/NC basis only.

Mechanics, sound. Meets New Mexico Lower-Division General Education Common Core Curriculum Area III: Science (NMCCN 1214).

Pre- or corequisite: MATH 162

Mechanics, sound. Meets New Mexico Lower-Division General Education Common Core Curriculum Area III: Science (NMCCN 1214). Three hours lab.

Pre- or corequisite: 160

Heat, electricity, magnetism. Meets New Mexico Lower-Division General Education Common Core Curriculum Area III: Science (NMCCN 1224).

Prerequisite: 160

Pre- or corequisite: MATH 163

Electricity and magnetism. Meets New Mexico Lower-Division General Education Common Core Curriculum Area III: Science (NMCCN 1224). Three hours lab.

Pre- or corequisite: 161

Problem solving and demonstrations related to 160.

Corequisite: 160

Offered on a CR/NC basis only.

Problem solving and demonstrations related to 161.

Corequisite: 161

Offered on a CR/NC basis only.

Optics, modern physics.

Prerequisite: 161

Pre- or corequisite: MATH 264

Optics, modern physics. Three hours lab.

Pre- or corequisite: 262

Problem solving and demonstrations related to 262.

Corequisite: 262

Offered on a CR/NC basis only.

Application of computational techniques to problems in physics and astronomy. Topics include: matrices, interpolation, fitting of data, Runge-Kutta techniques, complex math, Fourier techniques.

Prerequisite: 262

Pre- or corequisite: Math 316

{Spring}

Advanced study of concepts of physics and astronomy, designed especially for science teachers and other non-traditional students. Cannot be used to satisfy major or minor program requirements for physics or astrophysics degrees.

Prerequisite: 102 or ASTR 101 or NTSC 261L

Concepts of heat and thermodynamics; large numbers and probability distributions; spin, oscillator, and gas systems; simple interacting systems, Fermi and Bose statistics.

Prerequisite: 330

{Fall}

Geometrical optics; wave optics; lasers, nonlinear optics.

{Alternate Years}

Laboratory experiments in geometrical optics, diffraction, prisms, gratings, microscopy and imaging, polarization, interference and interferometry, and laser operation.

{Spring}

Dynamics of particles and rigid bodies, harmonic motion, gravitation, Lagrange's & Hamilton's equations, moving coordinate systems.

Prerequisite: MATH 311 and MATH 316

{Fall}

Mechanics of continuous media, rotations of rigid bodies, small oscillations, nonlinear and chaotic motions.

Prerequisite: 303 and MATH 312

{Spring}

Experiments in modern physics and experimental methods. One lecture, 3 hours lab.

{Fall}

Contemporary electronics. One lecture, 3 hours lab.

{Spring}

Problem solving and demonstrations related to PHYC 301.

Offered on CR/NC basis only.

Problem solving and demonstrations related to PHYC 303.

Prerequisite: MATH 311 and 316

Offered on CR/NC basis only.

Problem solving and demonstrations related to PHYC 304.

Prerequisite: 303 and MATH 312

Offered on CR/NC basis only.

(Also offered as EPS 427)

Applications of gravity, magnetics, seismology, heat flow to the structure, constitution and deformation of earth. Related aspects of plate tectonics and resource exploration.

Prerequisite: 161 and MATH 163 and (EPS 101 or ENVS 101)

Special relativity; quantum effects; introductory quantum mechanics; atomic and subatomic physics; instruments of modern physics.

Prerequisite: 262

{Spring}

Problem solving and demonstrations related to PHYC 330.

Prerequisite: 262

Offered on CR/NC basis only.

Student presentations, both extemporaneous and prepared, of undergraduate physics problems.

Offered on CR/NC basis only.

Electrostatics, magnetostatics; theory of dielectric materials; direct and alternating circuit theory.

Prerequisite: MATH 311 and MATH 316

{Spring}

Maxwell's equations; propagation, reflection and refraction of plane waves; wave guides; dipole radiation; stress-energy of the fields; relativistic fields.

Prerequisite: 405 and MATH 312

{Fall}

(Also offered as NSMS 410/510)

Students study chemical and physical concepts necessary to understand nanoscale materials: Quantum properties, charge confinement, and nanoscale thermodynamics, surface and interfacial forces, nanomachines and nanostructures, self-organization, and scaling. Emphasis on problem-solving skills development.

{Fall}

Problem solving and demonstrations related to PHYC 405.

Prerequisite: 316 and MATH 311.

Offered on CR/NC basis only.

Problem solving and demonstrations related to PHYC 406.

Prerequisite: 405 and MATH 312

Offered on CR/NC basis only.

Free electron gas, energy bands, crystals, semiconductors, metals, elementary excitations, superconductivity.

Prerequisite: 330

{Alternate years}

Introductory topics in elementary-particle physics and nuclear physics, with examples and applications to high-energy physics and astrophysics such as cosmic rays, fixed-target experiments, lepton and hadron colliders, stellar physics, supernovae and cosmology.

Prerequisite: 491

{Alternate Springs}

Offered on a CR/NC basis only.

(Also offered as ASTR 456)

Independent studies course for students seeking departmental honors.

{Fall, Spring}

(Also offered as ECE 463)

Electromagnetic theory of geometrical optics, Gaussian ray tracing and matrix methods, finite ray tracing, aberrations, interference.

{Fall}

(Also offered as ECE 464)

Resonator optics. Rate equations; spontaneous and stimuated emission; gas, semiconductor and solid state lasers, pulsed and mode-locked laser techniques.

{Fall}

Complex variables and analysis; differential equations, including Green's functions; transform methods; special functions; linear algebra; matrix analysis; linear integral equations.

{Fall}

Methods of theoretical physics such as tensor analysis, group theory, calculus of variations, and elementary statistics. The actual topic areas will vary and will be defined by the instructor.

{Alternate Springs}

Problem solving and demonstrations related to PHYC 466.

Offered on CR/NC basis only.

Problem solving and demonstrations related to PHYC 467.

Offered on CR/NC basis only.

Diffraction, interference, optical detectors, lens aberrations, lasers, spectra, scattering, optical testing. One lecture, 3 hours lab.

{Spring}

Diffraction, interference, optical detectors, lens aberrations, lasers, spectra, scattering, optical testing. One lecture, 3 hours lab.

{Spring}

Special topics beyond our standard curriculum, usually involving new areas. The actual topic areas will vary and will be defined by the instructor.

Restriction: permission of instructor.

Schrödinger Equations; Heisenberg uncertainty principle; postulates; Dirac notation; one-dimensional potentials; harmonic oscillator; angular momentum; H-Atom.

Prerequisite: 330 and MATH 321

{Fall}

Spin; Pauli principle; perturbation theory; scattering; applications of quantum mechanics.

Prerequisite: 491

{Spring}

Spectrographic methods; lasers, atomic structure; high Tc superconductivity; natural and artificial radioactivity; cosmic rays. One lecture, 5 hours lab.

{Spring}

Relativistic kinematics and dynamics, relativistic electromagnetism, application to subatomic physics and astrophysics.

{Offered upon demand}

Problem solving and demonstrations related to PHYC 491.

Prerequisite: 330 and MATH 321

Offered on CR/NC basis only.

Problem solving and demonstrations related to PHYC 492.

Offered on CR/NC basis only.

Review of Lagrangian dynamics; two-body central force; rigid-body motion; small oscillations; Hamilton’s equations; canonical transformations; Hamilton-Jacobi theory.

{Fall}

Review of thermodynamics; classical statistical mechanics; ensemble theory; quantum statistical mechanics with examples.

{Spring}

Review of electro- and magneto-statics; E&M waves and radiation; covariant electrodynamics; scattering; relativity and covariant collisions.

{Spring}

Review of 1-dim. potentials; Dirac formalism; postulates; symmetries and conservation laws; harmonic oscillator; angular momentum and spin; central potentials; approximation methods.

{Fall}

More on angular momentum; scattering; identical particles; spectra of atoms and molecules; symmetry and conservation laws; approximation methods; special topics.

Prerequisite: 521

{Spring}

Introduction to relativistic quantum mechanics, and quantum mechanics and quantum field theory with applications drawn from quantum electrodynamics and high-energy physics.

Prerequisite: 522

{Alternate Years}

A continuation of 523.

Prerequisite: 523

{Offered upon demand}

Band concepts; Bloch functions; phonons and their interactions; superconductivity.

{Alternate Falls}

One-, two-, and many-electron atoms; interactions with E&M radiation; fine and superfine structure; external fields; molecular structure and spectra; collisions; applications of atomic and molecular physics.

{Alternate years}

(Also offered as ECE 534)

Plasma parameters, adiabatic invariants, orbit theory, plasma oscillations, hydromagnetic waves, plasma transport, stability, kinetic theory, nonlinear effects, applications.

{Fall}

Derivation of fluid equations; CGL, MCD; equilibrium in the fluid plasma; energy principle; Rayleigh-Taylor, two-stream, and firehose instabilities; applications to lCF and open- and closed-line magnetic confinement systems; nonlinear instability theory.

Restriction: permission of instructor.

{Alternate Springs}

(Also offered as ASTR 536)

Astrophysical problems illustrating E&M and classical/statistical mechanics: expansion of the universe; dark matter; big-bang nucleosynthesis; stellar interiors; neutron stars; supernovae. May be repeated when topics are different.

{Alternate Falls}

Selected topics in methods of theoretical and computational physics.

{Offered upon demand}

Overview of the standard model, including electroweak interactions, gauge theories, QCD, other selected topics.

{Alternate Falls}

Galatic cosmic rays, Stormer theory, secondary cosmic rays in earth's atmosphere and environmental effects, time variations, particle detectors, heliopheric transport, extensive air showers, origin of cosmic rays.

Prerequisite: 406 and 491

Restriction: permission of instructor.

Offered on a CR/NC basis only.

(Also offered as ECE 554)

Diffractions theory, coherence theory, coherent objects, and incoherent imaging, and polarization.

Prerequisite: 463

{Spring}

(Also offered as ECE 559)

Students do research and/or development work at a participating industry or government laboratory in any area of optical science and engineering.

Restriction: permission of department.

Semiclassical laser theory, mode problems, pulse propagation, self-induced transparency, phase conjugate optics, photon statistics. May include semiconductor lasers, ultrafast phenomena, waveguides.

Prerequisite: 464

{Alternate Springs}

Study and manipulation of quantum coherence with electromagnetic fields. Quantum coherent spectroscopy; photon statistics and nonclassical light; open quantum systems; decoherence; special topics.

{Alternate Years}

General concepts, microscopic approach, nonlinear optical effects and devices.

{Alternate Springs}

Possible topics include dye lasers, solid-state lasers, novel lasers, interaction between intense lasers and matter, advanced nonlinear optics, spectroscopy.

{Offered upon demand}

Einstein’s theory of general relativity both as a theoretical model for gravitational forces via curved space times and as applied to various realistic astrophysical situations such as neutron stars, black holes and gravitational waves.

{Offered upon demand}

(Also offered as CS, NSMS 571)

This course explores the concepts and mathematical techniques underlying quantum computation. Topics include quantum entanglement, quantum cryptography, teleportation, models for quantum computation, quantum algorithms, quantum error correction, and fault-tolerant quantum computation.

Concepts, applications and mathematical techniques of quantum information theory. Topics include classical information, Hilbert-space formulation of quantum mechanics, quantum states, quantum dynamics and measurements, quantum information, and quantum entanglement.

(Also offered as ECE 580)

Plasma kinetics equations, Vlasov theories of plasma waves and microinstabilities, Landau damping, nonlinear evolution of instabilities, turbulence, applications, transport in fluid plasmas; Fokker-Planck, Krook collision model.

Prerequisite: 534, 535

{Offered upon demand}

Only 6 hours will count toward the program of studies.

Offered on a CR/NC basis only.

May be repeated with any single faculty member.

Offered on a CR/NC basis only.