Semester Syllabus PDF
ECE - Regulation 2021
PH3254 Physics for Electronics Engineering Syllabus - Anna University
Access the updated Anna University PH3254 syllabus for Physics for Electronics Engineering on LearnSkart. This Anna University subject syllabus PDF presents the updated semester 2 syllabus aligned with Regulation 2021 for Electronics and Communication Engineering students and related branches. It covers unit-wise subject unit topics and supports exam preparation syllabus planning for internal assessments and semester examinations under Anna University engineering syllabus standards.
Whole Syllabus PDF
ECE - Regulation 2021
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On this page, you will find the complete Anna University syllabus for PH3254 Physics for Electronics Engineering (Regulation 2021), tailored for Electronics and Communication Engineering students. You can easily view the syllabus directly online or download the official syllabus PDF for offline access. The syllabus is organized unit-wise, making it simple to understand each topic and plan your studies effectively. This helps you prepare for semester exams, internal assessments, and manage your learning schedule with confidence. All content is accurate, up-to-date, and follows the latest Anna University guidelines, ensuring you have reliable information for your academic needs. Whether you are revising for exams or checking specific units, this page provides a trustworthy resource for exam preparation, engineering notes, and understanding the subject structure. Accessing the syllabus here supports your academic journey with clarity and ease.
PH3254 PHYSICS FOR ELECTRONICS ENGINEERING
L T P C
3 0 0 3
COURSE OBJECTIVES:
- To make the students to understand the basics of crystallography and its importance in studying materials properties.
- To understand the electrical properties of materials including free electron theory, applications of quantum mechanics and magnetic materials.
- To instil knowledge on physics of semiconductors, determination of charge carriers and device applications
- To establish a sound grasp of knowledge on different optical properties of materials, optical displays and applications
- To inculcate an idea of significance of nano structures, quantum confinement and ensuing nano device applications.
UNIT I CRYSTALLOGRAPHY
Crystal structures: Crystal lattice – basis - unit cell and lattice parameters – crystal systems and Bravais lattices – Structure and packing fractions of SC, BCC, FCC, diamond cubic, NaCL, ZnS structures – crystal planes, directions and Miller indices – distance between successive planes – linear and planar densities – crystalline and noncrystalline materials –Example use of Miller indices: wafer surface orientation – wafer flats and notches – pattern alignment - imperfections in crystals.
UNIT II ELECTRICAL AND MAGNETIC PROPERTIES OF MATERIALS
Classical free electron theory - Expression for electrical conductivity – Thermal conductivity, expression - Quantum free electron theory :Tunneling – degenerate states – Fermi- Dirac statistics – Density of energy states – Electron in periodic potential – Energy bands in solids – tight binding approximation - Electron effective mass – concept of hole. Magnetic materials: Dia, para and ferromagnetic effects – paramagnetism in the conduction electrons in metals – exchange interaction and ferromagnetism – quantum interference devices – GMR devices.
UNIT III SEMICONDUCTORS AND TRANSPORT PHYSICS
Intrinsic Semiconductors – Energy band diagram – direct and indirect band gap semiconductors – Carrier concentration in intrinsic semiconductors – extrinsic semiconductors - Carrier concentration in N-type & P-type semiconductors – Variation of carrier concentration with temperature – Carrier transport in Semiconductors: Drift, mobility and diffusion – Hall effect and devices – Ohmic contacts – Schottky diode.
UNIT IV OPTICAL PROPERTIES OF MATERIALS
Classification of optical materials – Optical processes in semiconductors: optical absorption and emission, charge injection and recombination, optical absorption, loss and gain. Optical processes in quantum wells – Optoelectronic devices: light detectors and solar cells – light emitting diode – laser diode - optical processes in organic semiconductor devices –excitonic state – Electro-optics and nonlinear optics: Modulators and switching devices – plasmonics.
UNIT V NANO DEVICES
Density of states for solids - Significance between Fermi energy and volume of the material – Quantum confinement – Quantum structures – Density of states for quantum wells, wires and dots – Band gap of nanomaterials –Tunneling – Single electron phenomena – Single electron Transistor. Conductivity of metallic nanowires – Ballistic transport – Quantum resistance and conductance – Carbon nanotubes: Properties and applications - Spintronic devices and applications – Optics in quantum structures – quantum well laser.
TOTAL: 45 PERIODS
COURSE OUTCOMES:
At the end of the course, the students should be able to
- CO1: Know basics of crystallography and its importance for varied materials properties
- CO2: Gain knowledge on the electrical and magnetic properties of materials and their applications
- CO3: Understand clearly of semiconductor physics and functioning of semiconductor devices
- CO4: Understand the optical properties of materials and working principles of various optical devices
- CO5: Appreciate the importance of nanotechnology and nanodevices.
TEXTBOOKS:
- S.O. Kasap. Principles of Electronic Materials and Devices, McGraw Hill Education (Indian Edition), 2020.
- R.F.Pierret. Semiconductor Device Fundamentals. Pearson (Indian Edition), 2006.
- G.W.Hanson. Fundamentals of Nanoelectronics. Pearson Education (Indian Edition), 2009.
REFERENCES:
- Laszlo Solymar, Walsh, Donald, Syms and Richard R.A., Electrical Properties of Materials, Oxford Univ. Press (Indian Edition) 2015.
- Jasprit Singh, Semiconductor Optoelectronics: Physics and Technology, McGraw-Hill Education (Indian Edition), 2019.
- Charles Kittel, Introduction to Solid State Physics, Wiley India Edition, 2019.
- Mark Fox, Optical Properties of Solids, Oxford Univ.Press, 2001.
- N.Gershenfeld. The Physics of Information Technology. Cambridge University Press, 2011.
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