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| ====== General Information for PH575, Spring 2019 ====== | ====== General Information for PH575, Spring 2019 ====== |
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| This course provides an introduction to the physics of condensed matter for graduate students in physics, chemistry and engineering areas in which materials science is important. Senior undergraduates in physics will also find the course accessible. Topics include the theoretical basis of the electronic structure of solids, viewed from the real-space perspective of the interactions between atoms; the free electron description and physical properties of electrically conducting materials; semiconductors; optical properties of materials; the origins of magnetism; lattice excitations (phonons), and nanoscience. The goal is to understand the concepts underlying modern condensed matter physics and to become familiar with some of the experimental and computational techniques available to test those concepts. A major project is the computation of the band structure of a real material using density functional theory. | Introduction to Solid State Physics (PH575) is a 3-credit course that provides an introduction to the physics of condensed matter for graduate students in physics, chemistry and engineering areas in which materials science is important. Senior undergraduates in physics will also find the course accessible. Topics include the theoretical basis of the electronic structure of solids, viewed from the real-space perspective of the interactions between atoms; the free electron description and physical properties of electrically conducting materials; semiconductors; optical properties of materials; the origins of magnetism; lattice excitations (phonons), and nanoscience. The goal is to understand the concepts underlying modern condensed matter physics and to become familiar with some of the experimental and computational techniques available to test those concepts. A major project is the computation of the band structure of a real material using density functional theory. |
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| **Detailed syllabus** is found at [[http://www.physics.oregonstate.edu/~tate/COURSES/ph575]] | **Detailed syllabus** is found at [[http://www.physics.oregonstate.edu/~tate/COURSES/ph575]] |
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| ===== Times, Dates and Locations ===== | ===== Key Information ===== |
| * Class meets MWF at 3:00 pm - 3:50 pm in WGR 304 | |
| * Midterm 1 - Friday week 5; Midterm 2 - Wednesday week 8, both in class. | |
| * The [[http://catalog.oregonstate.edu/ChapterDetail.aspx?key=371#Section3674|final exam]] is on (Time TBA) in (Location TBA, probably Weniger 304). | |
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| ===== Instructors ===== | === Prerequisites === |
| | * PH451 or equivalent. Please discuss with instructor. |
| | === Instructors === |
| * [[http://www.physics.oregonstate.edu/~tate/|Prof. Janet Tate]], Weniger 485; 737-1700; tate at physics.oregonstate.edu | * [[http://www.physics.oregonstate.edu/~tate/|Prof. Janet Tate]], Weniger 485; 737-1700; tate at physics.oregonstate.edu |
| * [[http://www.physics.oregonstate.edu/~tate/schedule.html|Office hours (to be confirmed):]] Wednesdays 10-11; Thursdays 1:30-2:30; or by appointment | * [[http://www.physics.oregonstate.edu/~tate/schedule.html|Office hours (to be confirmed):]] Wednesdays 10-11; Thursdays 1:30-2:30; or by appointment |
| * TA: Mitchell Senger (sengermi at onid.oregonstate.edu) | * TA: Mitchell Senger (sengermi at onid.oregonstate.edu) |
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| | === Times, Dates and Locations === |
| | * Class meets MWF at 3:00 pm - 3:50 pm in WNGR 304 |
| | * Midterm 1 - Friday week 5; Midterm 2 - Wednesday week 8, both in class. |
| | * The [[http://catalog.oregonstate.edu/ChapterDetail.aspx?key=371#Section3674|final exam]] is on (Time TBA) in (Location TBA, probably Weniger 304). |
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| ===== Canvas for email list & grades: ===== | ===== Canvas for email list & grades: ===== |
