|
Programs:
Majors: Physics (options:
General; Applied); Pre-Engineering
Preparation (options: General, Metallurgical, and Chemical)
Minors: Astronomy; Physics;
Applied Physics (options: Electronics;
Solar energy)
Teaching Major: Science
(Primary area: Physics; Supporting area: Physics)
Teaching Minor:
Physics
Endorsement:
Physical Science
Courses:
PHYCS: Physics
APHYS: Applied Physics
ASTRO: AstronomyThe Department of Physics and
Astronomy offers two options for majors in physics plus programs for
minors in astronomy and physics. The general physics option is for students who want to pursue
graduate work in physics, astronomy, or engineering, and the applied
physics option is for students who are interested in careers in
industry. Minors in physics, applied physics, and astronomy are
available for students who have an interest in those areas but are
majoring in other fields.
Several options are
open for students who are planning careers as teachers in secondary
education. A teaching major with either a primary area or a
supporting area in physics is available. A teaching minor in physics
is also available for students with majors in areas such as
mathematics.
Students planning to major or minor
in physics or astronomy programs are strongly advised to consult with the department to
determine the proper course sequence for their needs.
This
pre-engineering major is
generally a five-year program in which students typically attend
Ball State for three years and then transfer to an engineering
school to finish their engineering degree requirements. Upon successful completion of the engineering program
a student is eligible to receive a bachelor's degree from Ball State in addition to
the
engineering degree. Students in this program are responsible for knowing and
meeting the requirements of the schools to which they plan to transfer.
Admission to Ball State as a
pre-engineering major does not guarantee admission to any accredited school of
engineering. Students must apply for admission to the desired engineering school and must
meet the requirements set by that engineering school. Three options in the pre-engineering
major are available: chemical engineering, metallurgical engineering, and general
engineering, including aeronautical, civil, electrical, industrial, mechanical, and
nuclear specializations.
Programs
Students will be guided by the
outline of baccalaureate Degrees, the
University Core
Curriculum, and the
concentration areas listed below.
| MAJOR
IN PHYSICS, 59-61 hours |
|
|
|
|
| PREFIX |
NO |
SHORT TITLE |
CR HRS |
| Common core,
47 hours |
| PHYCS |
120 |
Gen Phycs 1 |
5 |
|
122 |
Gen Phycs 2 |
5 |
|
260 |
Intro Modern |
3 |
|
262 |
Modern Lab |
1 |
|
330 |
Mechanics |
3 |
|
340 |
Physcl Optic |
3 |
|
434 |
Thermodynamc |
3 |
|
450 |
Elect Magnet |
3 |
|
464 |
Intro Q M |
3 |
|
482 |
Indpen Study
(3) |
|
|
or |
|
|
|
369 |
Prof Exper
(1-3) |
|
|
or |
|
|
|
479 |
Prac Exper
(1-3) |
|
|
or |
|
|
| HONRS |
499 |
Honors Proje
(3) |
3 |
| CS |
120 |
Comp Sci 1 |
3 |
| MATHS |
165 |
Calculus 1 |
4 |
|
166 |
Calculus 2 |
4 |
|
267 |
Calculus 3 |
4 |
|
|
|
______ |
|
|
|
47 hrs |
| Complete one option |
| Option 1: Physics (general), 12
hours |
| PHYCS |
452 |
Electrom Th |
3 |
|
465 |
Quant Mech |
3 |
| Electives from departmental
courses as approved by the student's departmental advisor and the department chairperson. |
6 |
|
|
|
______ |
|
|
|
12 hrs |
|
|
|
|
| Option 2: Physics (applied), 14
hours |
| 14 hours from |
|
|
|
| ASTRO |
330 |
Astrophycs 1 (4) |
|
|
332 |
Astrophycs 2 (4) |
|
| APHYS |
420 |
Solar Ener 1 (4) |
|
|
422 |
Solar Ener 2 (4) |
|
| PHYCS |
354 |
Electronic 1 (4) |
|
|
356 |
Electronic 2 (4) |
14 hrs |
|
|
|
______ |
|
|
|
59-61 hrs |
|
|
|
|
| Other PHYCS courses at the 300
level and above, with the approval of the student's departmental advisor and the
department chairperson, may be applied to option 2. |
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| MINOR
IN ASTRONOMY, 24 hours |
|
|
|
|
| PREFIX |
NO |
SHORT TITLE
|
CR HRS
|
| MATHS |
161 |
Appl Calc 1 |
3 |
|
162 |
Appl Calc 2 |
3 |
| PHYCS |
120 |
Gen Phycs 1 |
5 |
|
122 |
Gen Phycs 2 |
5 |
| ASTRO |
330 |
Astrophycs 1 |
4 |
|
332 |
Astrophycs 2 |
4 |
|
|
|
______ |
|
|
|
24 hrs |
|
|
|
|
| MATHS 165, 166 may be substituted
for MATHS 161, 162. |
(back to top)
| MINOR
IN PHYSICS, 26 hours |
|
|
|
|
| PREFIX |
NO |
SHORT TITLE |
CR HRS |
| PHYCS |
120 |
Gen Phycs 1 |
5 |
|
122 |
Gen Phycs 2 |
5 |
|
260 |
Intro Modern |
3 |
|
262 |
Modern Lab |
1 |
|
330 |
Mechanics |
3 |
|
450 |
Elect Magnet |
3 |
| MATHS |
161 |
Appl Calc 1 |
3 |
|
162 |
Appl Calc 2 |
3 |
|
|
|
______ |
|
|
|
26 hrs |
|
|
|
|
| MATHS 165, 166 may be substituted
for MATHS 161, 162. |
| MATHS 267 is waived as
prerequisite on PHYCS 450 for the minor, though recommended as an elective. |
(back to top)
| MINOR IN APPLIED PHYSICS, 24 hours |
|
|
|
|
| PREFIX |
NO |
SHORT
TITLE |
CR HRS |
| MATHS |
161 |
Appl Calc
1 |
3 |
|
162 |
Appl Calc 2 |
3 |
| PHYCS |
120 |
Gen Phycs 1 |
5 |
|
122 |
Gen Phycs 2 |
5 |
|
|
|
______ |
|
|
|
16 hrs |
| Complete one option |
| Option 1: Electronics, 8 hours
|
|
|
|
|
| PHYCS |
354 |
Electronic 1 |
4 |
|
356 |
Electronic 2 |
4 |
|
|
|
______ |
|
|
|
8 hrs |
| Option 2: Solar Energy, 8 hours
|
| APHYS |
420 |
Solar Ener 1 |
4 |
|
422 |
Solar Ener 2 |
4 |
|
|
|
______ |
|
|
|
8 hrs |
|
|
|
______ |
|
|
|
24 hrs |
|
|
|
|
| To begin this program it is
expected that students will have completed high school mathematics courses equivalent to
the prerequisite for MATHS 161. MATHS 165, 166 may be substituted for MATHS 161, 162. |
(back to top)
| TEACHING MAJOR IN SCIENCE, 54-58
hours |
| (See Teaching Major in
Science
,
College of Sciences and Humanities, for total requirements for this area.) |
|
|
|
|
| Primary area: physics,
31 hours |
| PREFIX |
NO |
SHORT TITLE |
CR HRS |
| PHYCS |
120 |
Gen Phycs 1 |
5 |
|
122 |
Gen Phycs 2 |
5 |
|
260 |
Intro Modern |
3 |
|
262 |
Modern Lab |
1 |
|
330 |
Mechanics |
3 |
|
354 |
Electronic 1 |
4 |
|
450 |
Elect Magnet |
3 |
|
482 |
Indpen Study (1-3) |
1 |
| MATHS |
161 |
Appl Calc 1 |
3 |
|
162 |
Appl Calc 2 |
3 |
|
|
|
______ |
|
|
|
31 hrs |
|
|
|
|
| MATHS 165, 166 may be substituted
for MATHS 161, 162. |
|
|
| Supporting area:
physics, 19-22 hours |
| PREFIX |
NO |
SHORT TITLE |
CR HRS |
| Complete one option |
| Option 1: 22 hours |
| PHYCS |
120 |
Gen Phycs 1 |
5 |
|
122 |
Gen Phycs 2 |
5 |
|
260 |
Intro Modern |
3 |
|
262 |
Modern Lab |
1 |
|
482 |
Indpen Study (1-3) |
2 |
| MATHS |
161 |
Appl Calc 1 |
3 |
|
162 |
Appl Calc 2 |
3 |
|
|
|
______ |
|
|
|
22 hrs |
|
|
|
|
| Option 2: 19 hours |
| PHYCS |
110 |
Gen Phycs 1 |
4 |
|
112 |
Gen Phycs 2 |
4 |
|
396 |
Tch Physics (1-3) |
2 |
| 9 hours of electives in PHYCS
approved by the department chairperson |
9 |
|
|
|
______ |
|
|
|
19 hrs |
|
|
|
|
| Option 2 is open only to certified
teachers; permission of the department chairperson is required before entrance into the
program. |
|
|
|
|
| MATHS 165, 166 may be substituted
for MATHS 161, 162. |
(back to top)
| TEACHING MINOR IN PHYSICS, 25 hours |
|
|
|
|
| PREFIX |
NO |
SHORT TITLE |
CR HRS |
| PHYCS |
120 |
Gen Phycs 1 |
5 |
|
122 |
Gen Phycs 2 |
5 |
|
260 |
Intro Modern |
3 |
|
262 |
Modern Lab |
1 |
|
330 |
Mechanics |
3 |
|
450 |
Elect Magnet |
3 |
| 5 hours from |
| PHYCS |
340 |
Physcl Optic (3) |
|
|
354 |
Electronic 1 (4) |
|
|
356 |
Electronic 2 (4) |
|
|
360 |
Nuclear Tech (3) |
|
|
370 |
Math Phys 1 (3) |
|
|
452 |
Electrom Th (3) |
|
|
461 |
Elemen Part (3) |
|
|
463 |
Nuclear (3) |
|
|
464 |
Intro Q M (3) |
|
|
465 |
Quant Mech (3) |
|
|
466 |
Cond Matter (3) |
|
|
482 |
Indpen Study (1-3) |
5 |
|
|
|
______ |
|
|
|
25 hrs |
|
|
|
|
| Courses in mathematics through
MATHS 166 or its equivalent are required. |
(back to top)
| ENDORSEMENT IN PHYSICAL SCIENCE, 23 hours |
| For elementary education majors |
|
|
|
|
| PREFIX |
NO |
SHORT TITLE |
CR HRS
|
| PHYCS |
102 |
Sci Tch Matr |
3 |
| ASTRO |
101 |
Matr for Tch |
3 |
| CHEM |
100 |
People Chem |
3 |
| 14 hours from |
| PHYCS |
184 |
Sound Light (3) |
|
|
200 |
Topics Phycs (1-3) |
|
|
220 |
Solar Energy (3) |
|
|
482 |
Indpen Study (1-3) |
|
| ASTRO |
102 |
Observationl (3) |
|
|
200 |
Topics Astro (1-3) |
|
| GEOG |
101 |
Erth Sea Sky (3) |
|
|
or |
|
|
| GEOL |
101 |
Planet Earth (3) |
|
| NREM |
331 |
Enrg Min Res (3) |
|
|
or |
|
|
|
341 |
Air Quality (3) |
14 |
|
|
|
______ |
|
|
|
23 hrs |
(back to top)
| MAJOR IN PRE-ENGINEERING PREPARATION,
62-72 hours |
|
|
|
|
| PREFIX |
NO |
SHORT TITLE |
CR HRS |
| Common core, 51 hours |
| PHYCS |
120 |
Gen Phycs 1 |
5 |
|
122 |
Gen Phycs 2 |
5 |
|
260 |
Intro Modern |
3 |
|
262 |
Modern Lab |
1 |
|
330 |
Mechanics |
3 |
|
354 |
Electronic 1 |
4 |
| CHEM |
111 |
Gen Chem 1 |
4 |
|
112 |
Gen Chem 2 |
4 |
| CS |
120 |
Comp Sci 1 |
3 |
| ITMFG |
105 |
Tec Dsgn Gra |
3 |
| MATHS |
165 |
Calculus 1 |
4 |
|
166 |
Calculus 2 |
4 |
|
217 |
Lin Algebra |
4 |
|
267 |
Calculus 3 |
4 |
|
|
|
______ |
|
|
|
51 hrs |
| Complete one option as approved by
the pre-engineering advisor. |
|
|
|
|
| Option 1: General (civil,
electrical, mechanical, nuclear) 12 hours |
| PHYCS |
356 |
Electronic 2 |
4 |
| 8 hours from |
| electives in PHYCS, APHYS, CS, and
MATHS as approved by the pre-engineering advisor |
8 |
|
|
|
______ |
|
|
|
12 hrs |
|
|
|
|
| Option 2: Metallurgical, 11
hours |
| CHEM |
225 |
Analysis |
3 |
|
344 |
Physl Chem 1 |
4 |
|
345 |
Physl Chem 2 |
4 |
|
|
|
______ |
|
|
|
11 hrs |
|
|
|
|
| Option 3: Chemical, 21 hours
|
| CHEM |
225 |
Analysis |
3 |
|
234 |
Organic Ch 1 |
5 |
|
235 |
Organic Ch 2 |
5 |
|
344 |
Physl Chem 1 |
4 |
|
345 |
Physl Chem 2 |
4 |
|
|
|
______ |
|
|
|
21 hrs |
|
|
|
______ |
|
|
|
62-72 hrs |
|
|
|
|
| To begin this program it is
expected that students will have completed high school mathematics courses equivalent to
the prerequisite for MATHS 165. |
(back to top)
COURSES:
PHYSICS (PHYCS)
100 Conceptual
Physics. (3)
Includes a survey of physics with conceptual emphasis on basic classical and modern
concepts of matter, motion, energy, and forces with application to mechanics, heat, sound,
electricity and magnetism, light, atomic, nuclear, and elementary particles.
101 Physical Science Concepts for Teachers. (1-3)
Principles and concepts of the laws of nature involving mechanical, heat, light,
electrical, nuclear, and chemical energy and the conservation laws associated with these
forms of energy. Emphasizes applications appropriate to the classroom. Designed primarily
for students in elementary education programs.
A total of 3 hours of credit may be earned.
102 Preparation of Physical Science Teaching
Materials. (3)
Selected topics in physical science stressing the construction of models and
experimentation appropriate to the classroom. Designed primarily for students in
elementary education programs.
Prerequisite: PHYCS 101 or permission of the department chairperson.
Open only to students in the teacher-education curriculum.
106 Basic Physics for the Allied Health Sciences.
(3)
A condensed study of basic physics with special emphasis on principles and applications
pertinent to the health sciences. Three lectures and one two-hour laboratory-recitation
weekly.
Prerequisite: one year of high school algebra and one year of high school geometry or
permission of the department chairperson.
Open only to students in the allied health sciences programs in respiratory therapy,
radiologic technology, nuclear therapy, and ultrasound technology or by permission of the
department chairperson.
110 General Physics 1. (4)
Studies the laws of Newtonian mechanics. Introductory fluid statics and dynamics, heat and
thermodynamics, and wave motion and sound.
Prerequisite: MATHS 108 (algebra).
Recommended prerequisite: MATHS 112 (trigonometry).
112 General Physics 2. (4)
Static and current electricity, magnetism, light and optics, and an introduction to modern
physics including relativity and elements of atomic and nuclear physics.
Prerequisite: PHYCS 110.
120 General Physics 1. (5)
First course in calculus-based physics for students in pre-engineering, the
physical sciences, or mathematics. Topics include Newtonian mechanics, work and energy,
motion, impulse and momentum, elasticity and wave motion, sound, and hydrostatics and
hydrodynamics.
Prerequisite or parallel: MATHS 161 or 165.
122 General Physics 2. (5)
Continuation of PHYCS 120. Topics include heat and laws of thermodynamics, Coulomb's law
and the electric field, Ampere's law and the magnetic field, introduction to Maxwell's
equation, DC and AC circuits; the nature, propagation, and properties of light; and lens
systems.
Prerequisite: PHYCS 120.
Parallel: MATHS 162 or 166.
140 General Physics 1 (Calculus-based). (4)
First course in calculus-based general physics. Topics include Newtonian mechanics, work
and energy, impulse and momentum, elasticity, wave motion and sound, hydrostatics and
hydrodynamics. Computer-based content delivery for self-paced learning.
Prerequisite or parallel: MATHS 161 or 165; permission of the department chairperson.
Not open to students who have credit in PHYCS 120.
141 General Physics 1 (Calculus-based) Lab.
(1)
Laboratory component to accompany PHYCS 140. Computer simulations and in-lab experiments
are performed.
Prerequisite or parallel: PHYCS 140.
Not open to students who have credit in PHYCS 120.
142 General Physics 2 (Calculus-based). (4)
Continuation of PHYCS 140. Topics include heat and thermodynamics, Coulomb's Law, electric
fields, magnetic fields, AC and DC circuits, geometric and physical optics. Computer-based
content delivery for self-paced learning.
Prerequisite: PHYCS 120 or 140; permission of the department chairperson.
Prerequisite or parallel: MATHS 162 or 166.
Not open to students who have credit in PHYCS 122.
143 General Physics 2 (Calculus-based) Lab. (1)
The laboratory component to accompany PHYCS 142. Computer simulations and in-lab
experiments are performed.
Prerequisite or parallel: PHYCS 142.
Not open to students who have credit in PHYCS 122.
184 Sound and Light. (3)
For music and art students. Sound as a basis of music and light
as a basis of art. No regularly scheduled laboratory.
200 Topics in
Physics. (1-3)
Discussion of specific topics in physics, such as lasers, holography, and solid-state
electronics. Designed for students not majoring in physics, the course requires no math or
science background. Students may consult their curricular advisors or the Department of
Physics and Astronomy for the specific topics being studied during a given semester.
A total of 3 hours of credit may be earned.
220 Introduction to Solar Energy Technology and
Applications. (3)
Descriptive study of various techniques and systems using sunlight as a nonpolluting
alternative energy source. Principles and design of solar systems for space heating, air
conditioning, and heating water for residential and commercial buildings, and systems for
the generation of electric power. Includes other related topics.
Prerequisite: PHYCS 100 or MATHS 108.
260 Introduction to Modern Physics. (3)
The underlying principles and theories of modern physics. Topics include introductory
relativity, atomic and nuclear structure, quantum theory, and the theory of solids.
Prerequisite: PHYCS 122.
262 Modern Physics Laboratory. (1)
Classic experiments such as the Cavendish measurement of G, determination of Planck's
Constant, Rutherford Scattering, Millikan Oil Drop Experiment, Franck-Hertz Experiment,
and the Hall Effect will be performed. Use of computer software for report generation will
be stressed.
Prerequisite: PHYCS 260.
330 Mechanics. (3)
Basic concepts of particle mechanics. Simple and damped harmonic motion. Particle dynamics
in noninertial frames of reference, central forces. Dynamics of a system of particles.
Dynamics of a rigid body and the moment of inertia tensor. The wave equation, elasticity,
and rigid body vibrations.
Prerequisite: PHYCS 120; MATHS 162.
Prerequisite recommended: MATHS 267.
340 Physical Optics. (3)
The electromagnetic wave theory of light, spectra, interference, diffraction,
polarization, and double refraction.
Prerequisite: PHYCS 122.
346 Acoustics. (3)
Elements of pure and applied acoustics. Topics include solutions to the wave equation,
acoustic impedances, electro-mechanical-acoustic analogies, direct-radiator loudspeaker
and enclosure theory, and a discussion of room acoustics.
Prerequisite: PHYCS 122.
354 Electronics 1. (4)
Introductory DC and AC circuit theory, semiconductor components, power supplies,
transistor amplification; integrated circuit operational amplifiers, active filters,
oscillators, and function generators. Basic combinational logic circuits and Boolean
algebra. Emphasizes applications of integrated circuits.
Prerequisite: PHYCS 122 or permission of the department chairperson.
356 Electronics 2. (4)
Sequential logic circuits including scalars, displays, memories, shift registers,
analog-to-digital and digital-to-analog conversion techniques. Microprocessor architecture
and support electronics for microcomputer design. IC chips and circuits for
experiment-to-microcomputer interfacing. Use of a microprocessor development system.
Prerequisite: PHYCS 354 or permission of the department chairperson.
360 Introductory Nuclear Techniques. (3)
Emphasizes experimental studies of radioactive disintegrations and decay products and
their relation to nuclear structure. Instrumentation in radioisotope measurements. Two
lectures and two two-hour laboratory periods a week.
Prerequisite: PHYCS 260.
369 Professional Experience. (1-3)
Paid work and learning experience in applied or theoretical physics or astronomy in an
institutional, industrial, or university research or development setting. May occur during
one or more semesters.
Prerequisite: approval of proposed program by the department chairperson.
A total of 3 hours of credit may be earned.
370 Introductory Mathematical Physics 1. (3)
Application of mathematical techniques to the formulation and solution of physical
problems in classical mechanics, thermodynamics,
electromagnetic theory, and quantum mechanics. Topics include computer
algebra systems and applications.
Prerequisite: PHYCS 122, 260; or permission of the department chairperson.
372 Introductory Mathematical Physics 2. (3)
Techniques in the formulation and solution of physical
problems. Computer Algebra systems (e.g. Mathematica) may be introduced
for the study of topics such as boundary value problems, transforms,
special functions of mathematical physics, and applications of tensor
analysis in physics.
Prerequisite: PHYCS 122, 260; or permission of the department chairperson.
380 Descriptive Astronomy. (3)
The celestial sphere, the solar system, formation and decay of stars, instruments and
basic laws of astronomy, nebulae, galactic structure, theories of the origin of the
universe; constellation and telescope work.
390 Honors Colloquium in Physics. (1-3)
Exploration of selected topics in physics, with emphasis on individual projects, study,
and discussion.
A total of 3 hours of credit may be earned.
Open only to honors students or with permission of the department chairperson.
396 The Teaching of Physics in the Secondary
School. (1-3)
Aims, nature of the subject matter, calculus concepts, and
applications in the teaching of physics; amount and nature of laboratory work,
standardized tests, and textbooks used in the teaching of physics. No regularly scheduled
laboratory.
Prerequisite: 16 hours of credit in physics or permission of the department chairperson.
A total of 3 hours of credit may be earned.
434 Thermodynamics.
(3)
Laws of thermodynamics and introduction to the kinetic theory of gases. No
regularly scheduled laboratory.
Prerequisite: PHYCS 330 or permission of the department chairperson.
450 Electricity and Magnetism. (3)
Application of vector analysis to electrostatics, dipole and multipole fields, and
dielectric theory, alternating currents, magnetic fields, and Maxwell's equation. No
regularly scheduled laboratory.
Prerequisite: PHYCS 122; MATHS 267.
452 Electromagnetic Theory. (3)
Electrostatic boundary-value problems, multipoles, dielectrics, magnetostatics, Maxwell's
equation, EM waves and radiation, plasmas, relativistic kinematics and dynamics, and
radiation of moving changes.
Prerequisite: PHYCS 450.
461 Elementary Particles. (3)
The nature and behavior of elementary particles through the study of the
symmetries and dynamics responsible for their production, reactions, and decays.
Prerequisite: PHYCS 465.
463 Nuclear Physics. (3)
Nucleus and nuclear interactions. Emphasizes experimental facts about nuclear
processes in discussions of particle accelerators, detectors, radioactivity (alpha, beta,
and gamma decay), interaction of radiation with matter, nuclear reactions, nuclear
structure, nuclear models, and nuclear applications in science and technology.
Prerequisite: PHYCS 260.
464 Introduction to Quantum Mechanics. (3)
De Broglie's postulate, the uncertainty principle, the Schroedinger equation, the
free particle, square well potentials, harmonic oscillator, the hydrogen atom, angular
momentum in quantum mechanics, and other selected wave mechanics problems. No regularly
scheduled laboratory.
Prerequisite: PHYCS 260.
465 Quantum Mechanics. (3)
Review of barrier problems, the harmonic oscillator, and angular momentum using
matrix methods. Problems involving perturbation theory, one-electron atoms, magnetic
moments, spin, relativistic effects, symmetric and anti-symmetric wave functions, the
helium atom, transition rates, and scattering theory.
Prerequisite: PHYCS 464.
466 Condensed Matter Physics. (3)
Structure and physical properties of matter in the solid state. Electrical and
magnetic properties, and band theory of solids with special emphasis on semiconductors.
Prerequisite: PHYCS 260.
479 Practical Experience. (1-3)
Unpaid work and learning experience in applied or theoretical physics or
astronomy in an institutional, industrial, or university research or development setting.
May occur during one or more semesters.
Prerequisite: approval of a proposed program by the department chairperson.
A total of 3 hours of credit may be earned.
482 Independent Studies in Physics. (1-3)
Pursuit of special lines of scientific investigation in physics on an individual
basis. Experimental work, wide reading, and development of research techniques and skills.
Prerequisite: permission of the department chairperson.
A total of 3 hours of credit may be earned.
(back to top)
APPLIED PHYSICS
(APHYS)
228 Radiation Physics
and Protection. (3)
Overview of radiation physics including properties of radiation, biological effects, X-ray
production and interaction, and radiation protection.
Prerequisite: MATHS 108; PHYCS 100 or 106.
247 Introduction to Radioactivity. (3)
Mechanisms and characteristics of nuclear decay and interaction of radiation with
matter.
Prerequisite: admission to associate in science degree program in nuclear
medicine or radiation therapy.
248 Radiopharmaceuticals. (2)
Preparation, quality control, and the diagnostic and therapeutic application of
radiopharmaceuticals in the nuclear medicine clinic.
Prerequisite: APHYS 247.
251 Nuclear Medicine Instrumentation. (4)
In-depth study of the components and performance characteristics of equipment commonly
used in the nuclear medicine clinic.
Parallel: APHYS 252.
252 Nuclear Medicine Instrumentation Lab. (1)
A weekly laboratory for nuclear medicine technology students enrolled in APHYS 251.
420 Applied Solar
Energy 1. (4)
A study of physics and engineering facets of the solar energy resource: solar collection,
concentration, thermal conversion, energy storage, and the design and performance of solar
thermal energy systems.
Prerequisite: PHYCS 122 and MATHS 162 or 166.
422 Applied Solar Energy 2. (4)
Physics and engineering of solar electric power generation with emphasis on
properties of solar cells and design, operation, and performance of photovoltaic systems.
Prerequisite: APHYS 420.
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ASTRONOMY (ASTRO)
100 Introductory
Astronomy: A Study of the Solar System and Beyond. (3)
Study of the physical nature of objects in the universe and methods used by astronomers to
understand them. Topics selected from basic laws of nature, the solar system, stars,
nebulae, galaxies, and cosmology.
101 Astronomy Materials for the Teacher. (3)
Fundamentals of astronomy including historical aspects and modern astronomy
concepts. Emphasizes construction of models and experimentation appropriate to the
classroom. Designed primarily for students in education programs.
102 Observational Astronomy. (3)
Continuation of ASTRO 100 providing practical experience in observing celestial objects by
using telescopes and other astronomical apparatus.
Prerequisite: ASTRO 100 or permission of the department chairperson.
120 Stars and Stellar Systems. (3)
Introduction to modern stellar astronomy. Topics include celestial coordinate systems,
gravity and orbital motion, light, properties of stars, stellar evolution, and the Milky
Way.
121 Honors Astronomy Laboratory. (1)
Introduction to observational stellar astronomy. The student will plan and execute
sessions in the Ball State University Observatory and analyze and interpret astronomical
data related to the determination of the properties of stars.
Prerequisite: permission of the instructor.
Parallel or Prerequisite: ASTRO 120.
122 Cosmology and Life in the Universe. (3)
Introduction to the large-scale structure of the universe, planetary systems, and
extraterrestrial life. Topics include galaxies, quasars, cosmology, planetary systems, and
life in the universe.
Prerequisite: ASTRO 120.
200 Topics in
Astronomy. (1-3)
Discussion of specific topics in astronomy, such as comets, eclipses, UFOs, and
interstellar travel. Designed for students not majoring in physics, the course requires no
math or science background. Students may consult their curricular advisors or the
Department of Physics and Astronomy for specific topics being studied during a given
semester.
A total of 3 hours of credit may be earned.
330 Astronomy and
Astrophysics 1. (4)
A review of mechanics, electromagnetic radiation, and atomic structure in the context of
modern observational astrophysics. Solar system astrophysics--including an introduction to
celestial mechanics and astronomical coordinate and time systems--are surveyed, and
astronomical instruments are discussed.
Prerequisite: PHYCS 120, 122.
332 Astronomy and Astrophysics 2. (4)
An examination of observational stellar astronomy with applications to the study of
stellar structure and evolution, and a review of the physics of stellar systems such as
star clusters, galaxies, and clusters of galaxies.
Prerequisite: ASTRO 330.
380 Seminar in Modern Astronomy. (3)
Selected topics in contemporary astronomy. Extensive use of library facilities including
current journals and periodicals in astronomy. Topics for study may include astronomical
research in progress and such esoteric subjects as UFOs and extraterrestrial life.
Prerequisite: PHYCS 122 and permission of the department chairperson.
382 Instruments and Techniques in Planetarium
Operations. (3)
Use of planetarium instruments, console, and chamber. Creation and presentation of
planetarium programs including slide-duplicating techniques, slide opaquing, and the
production of sound tracks.
Prerequisite: permission of the planetarium director.
386 Theories and Instruments of the Astronomer. (3)
Reviews of various atlases, catalogs, ephemerides, and charts. The development of methods
used to compute and update stellar positions. Discusses astronomical instruments in the
context of their use by research astronomers. Analyzes specific techniques employed in
astronomical photometry, spectroscopy, and photography.
Prerequisite: ASTRO 332.
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