Kurikulum 2024

Kode Mata KuliahFI4231 / 3 SKS
Penyelenggara102 - Physics / FMIPA
KategoriLecture
Bahasa IndonesiaEnglish
Nama Mata KuliahKapita Selekta Teknologi Devais KuantumSelected Topic Quantum Devices of Technology
Bahan Kajian
  1. Matakuliah ini membahas secara sistematis hal hal terkait nanosains dan nanoteknologi serta komputasi material maju dan devais nano. Adapun cakupan materi meliputi : Pendahuluan (Introduction), Fisika dalam Nanomaterial, Sintesis Nanomaterial, Karakterisasi Nanomaterial, Aplikasi Nanomaterial. Komputasi material maju dan devais nano meliputi simulasi sifat-sifat struktur, listrik, optik dan magnetik, serta pengaruhnya pada karakteristik devais elektronik, optik, magnetik dan kombinasinya.
  2. Matakuliah ini membahas secara sistematis hal hal terkait eksplorasi dan pemanfaatan fenomena kuantum untuk divais fungsional. Adapun cakupan materi meliputi : fisika dan teknologi sistem kuantum, fenomena kuantum dalam nanosystem dan efek quantum dalam divais.
  3. Matakuliah ini akan membahas prinsip-prinsip dasar fisika kuantum, termasuk superposisi, entanglement, dan ketidakpastian. Mahasiswa akan menjelajahi konsep-konsep ini dalam konteks pengembangan teknologi divais kuantum, memahami bagaimana prinsip-prinsip ini membentuk dasar bagi perangkat-perangkat kuantum.
  4. Matakuliah ini juga membahas aplikasi nanoteknologi dan penggunaan nanomaterial dalam pengembangan divais kuantum. Mahasiswa akan belajar tentang teknik fabrikasi nanomaterial, eksplorasi sifat unik nanomaterial, serta aplikasi nanoteknologi dalam perangkat kuantum seperti transistor nano dan sensor kuantum.
  5. Mahasiswa akan diberikan pengantar terkait aplikasi teknologi divais kuantum dalam bidang komputasi kuantum dan komunikasi kuantum yang berfokus pada konsep-konsep seperti kriptografi kuantum dan komputasi paralel dalam konteks pengembangan sistem komputasi dan komunikasi yang lebih aman dan efisien.
  1. This course systematically discusses matters related to nanoscience and nanotechnology as well as computing advanced materials and nanodevices. The material coverage includes: Introduction, Physics in Nanomaterials, Synthesis of Nanomaterials, Characterization of Nanomaterials, Applications of Nanomaterials. Computation of advanced materials and nanodevices includes simulation of structural, electrical, optical and magnetic properties, as well as their influence on the characteristics of electronic, optical, magnetic devices and their combinations
  2. This course systematically discusses matters related to the exploration and use of quantum phenomena for functional devices. The scope of material includes: physics and technology of quantum systems, quantum phenomena in nanosystems and quantum effects in devices
  3. This course will discuss the basic principles of quantum physics, including superposition, entanglement, and uncertainty. Students will explore these concepts in the context of quantum device technology development, understanding how these principles form the basis for quantum devices
  4. This course also discusses the application of nanotechnology and the use of nanomaterials in the development of quantum devices. Students will learn about nanomaterial fabrication techniques, explore the unique properties of nanomaterials, as well as the application of nanotechnology in quantum devices such as nanotransistors and quantum sensors
  5. Students will be given an introduction to the application of quantum device technology in the fields of quantum computing and quantum communications which focuses on concepts such as quantum cryptography and parallel computing in the context of developing safer and more efficient computing and communication systems.
Capaian Pembelajaran Mata Kuliah (CPMK)
  1. Mahasiswa memahami prinsip kerja divais nano
  2. Mahasiswa memahami proses fabrikasi divais nano
  3. Mahasiswa mengetahui divais nano dan potensi pengembangannya untuk masa depan
  4. Mampu menjelaskan fenomena kuantum untuk divais fungsional.
  5. Mampu menjelaskan prinsip-prinsip dasar fisika kuantum, termasuk superposisi, entanglement, dan ketidakpastian.
  6. Mampu menjelaskan aplikasi nanoteknologi dan penggunaan nanomaterial dalam pengembangan divais kuantum
  7. Mampu menjelaskan aplikasi teknologi divais kuantum dalam bidang komputasi kuantum
  1. Students understand the working principles of nanodevices
  2. Students understand the nano device fabrication process
  3. Students know about nano devices and their development potential for the future
  4. Able to explain quantum phenomena for functional devices.
  5. Able to explain the basic principles of quantum physics, including superposition, entanglement, and uncertainty.
  6. Able to explain the application of nanotechnology and the use of nanomaterials in the development of quantum devices
  7. Able to explain the application of quantum device technology in the field of quantum computing
Metode PembelajaranKuliah tatap muka, tutorial, riset sederhanaFace-to-face lectures, tutorials, simple research
Modalitas PembelajaranSistem fabrikasi, karakterisasi dan modeling system kuantum, alat peraga, video terkait divais kuantumFabrication systems, characterization and modeling of quantum systems, teaching aids, videos related to quantum devices
Jenis NilaiABCDE
Metode PenilaianUjian Tengah Semester, Ujian Akhir Semester, TugasMidterm Exam, Final Semester Exam, Assignments
Catatan TambahanMKPB