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Special Topics on Solid State Physics: Advances and Applications

Offered in 112-2

  • Serial Number

    35902

  • Course Number

    Phys8096

  • Course Identifier

    222 D3210

  • No Class

  • 3 Credits

  • Elective

    GRADUATE INSTITUTE OF PHYSICS / TIGP-MOLECULAR SCIENCE AND TECHNOLOGY

      Elective

    • GRADUATE INSTITUTE OF PHYSICS

    • TIGP-MOLECULAR SCIENCE AND TECHNOLOGY

  • MINN TSONG LIN
    • View Courses Offered by Instructor

    • COLLEGE OF SCIENCE GRADUATE INSTITUTE OF APPLIED PHYSICS

    • mtlin@phys.ntu.edu.tw

    • 理學院凝態物理館R625

    • 02-33665173

    • Professor Minn-Tsong Lin Department of Physics National Taiwan University http://web.phys.ntu.edu.tw/nanomagnetism/
  • Fri 7, 8, 9

  • 新物618

  • Type 2

  • 30 Student Quota

    NTU 30

  • No Specialization Program

  • English
  • NTU COOL
  • Core Capabilities and Curriculum Planning
  • Notes
    The course is conducted in English。

  • NTU Enrollment Status

    Enrolled
    0/30
    Other Depts
    0/0
    Remaining
    0
    Registered
    0
  • Course Description
    This is a seminar and discussion class, which will cover a wide range of topics concerning present-day Solid State Physics. Students will read about specific topics (chosen by themselves, with the guidance of the Professor), before giving presentations in the class. The participants are presenting to all the others. The content will include a clear introduction and applications which may arise.
  • Course Objective
    Students may choose ANY topic in modern Solid State Physics (apart from one's current research field) The followings are some examples, Quantum science and technology: quantum transport quantum computer quantum communication quantum materials spin entanglement quantum bit / qubit (updated 2023) Graphene: Physics, Synthesis, and Applications Transition metal dichalcogenides (e.g. MoS2) and other 2-D semiconductors Superconductivity (including high-Tc superconductors) Dielectricity and ferroelectricity Multiferroic materials Spintronics and spin dependant transport Topological Insulators and Quantum Spin Hall systems The Rashba and Dresselhaus effects The Hanle effect and spin-FETs Ferromagnetism and anti-ferromagnetism Half-metallic materials The Tunneling magneto-resistance (TMR) effect and magnetic tunneling junctions Organic spintronics Organic photovoltaics Molecular electronics The Kondo effect and the quantum blockade Plasmons, polarons and polaritons Optical processes and excitons Advanced nano-scale characterization techniques Scanning probe microscopy (SEM, STM, AFM, SPEM,...) etc...
  • Course Requirement
    SCIENTIFIC ETHICS. Citations must be clear in all kinds of presentations.
  • Expected weekly study hours after class
  • Office Hour

    Details would vary depending on the number of the participants, and will be settled in the first 2 weeks. Rescheduling is possible during the semester, and will be updated here on NTU COOL. Reaching TA: kuihon.oy@gmail.com

  • Designated Reading
  • References
    Introduction to Solid State Physics, 8th edition, Charles Kittel For paper report: https://journals.aps.org/revtex (REVTeX Home Page)
  • Grading
    35%

    Oral presentation_long

    1 talk of 20 minutes in English.

    35%

    Oral presentation_short

    2 Talks of 10 minutes in English.

    30%

    Paper report

    DUE DAY: 24:00 31May 2024. * Academic ethics is important. DO-NOT COPY and PASTE, citations must be well addressed. ** Working reports or group meeting reports are not allowed. *** Content should be different from one's oral presentations. 1 paper report in pdf format, 1-3 pages with at least 1 page of text. Please edit with LaTex, with PRL format (https://journals.aps.org/revtex).

    0%

    Attendance

    Absence without notifying MT and TA is only allowed once.

  • Adjustment methods for students
  • Course Schedule
    23FebWeek 1Introduction (1/2)_Prof. M.-T. Lin * All participants should show up.
    01MarWeek 2Introduction (2/2)_Prof. M.-T. Lin
    08MarWeek 3s1 Prabesh Bista_Exciton s2 Zhi-Long Yen_Ferromagnetism and anti-ferromagnetism
    15MarWeek 4** Class starts from 15:00. s2-rpt Zhi-Long Yen_Ferromagnetism and anti-ferromagnetism s3 Chih-Ying Huang_TEM s4 Avanish Kumar_quantum bit/qubit s14 Noy Gotlib_Dielectricity & Ferroelectricity
    22MarWeek 5s11 Yi-Chen Tsai_quantum computer s12 Shuan-Cheng Mai_The Kondo effect s13 Chun Wei Chang_Quantum Hall effect s14 Sania Majeed_STM
    29MarWeek 6-No class-
    05AprWeek 7-Holiday-
    12AprWeek 8-No class, week of Mid-term exam-
    19AprWeek 9s10 Zhi-Long Yen_TMD and other 2D semiconductors s16 Noy Gotlib_Photovotaics s17 Shuan-Cheng Mai_Organic spintronics s18 Chih-Ying Huang_Half-metallic materials s19 Yi-Chen Tsai_SEM s28 Moeen Ud Din s29 Chieh-Chun Chang
    26AprWeek 10-No class-
    03MayWeek 11-No class-
    10MayWeek 12s20 Avanish Kumar_Plasoms s27 Prabesh Bista L9 Jyun-Yang Siao_MOKE L3 Noy Gotlib_Multiferroic materials L4 Moeen Ud Din
    17MayWeek 13s22 Chun Wei Chang_Symmetry and Superconducting diode effect s23 Jyun-Yan Siao_Anomalous Hall effect s30 Moeen Ud Din_High-T superconductivity s26 Muhsin Punnoli_Water splitting L5 Shuan-Cheng Mai-Magic angle graphene L6 Avanish Kumar_superconductivity (high-Tc included) L7 Muhsin Punnoli_MXene: Emerging 2D material L12 Sania Majeed_organic photovoltaics
    24MayWeek 14s24 Muhsin Punnoli_Trichalcogenides s25 Sania Majeed_TMR effect s21 Jyun-Yan Siao_ FMR L8 Chun Wei Chang_Josephson Junction L2 Chih-Ying Huang_quantum materials L10 Yi-Chen Tsai_Graphene: Physics, Synthesis, and Applications L1 Zhi-Long Yen_SPM (2) L11 Prabesh Bista s31 Chieh-Chun Chang L13 Chieh-Chun Chang
    31MayWeek 15-No class- *Due day of the paper report.
    07JunWeek 16-Week of final exam-