| Bahan Kajian | - Definisi dan organisasi kursus 2. Sejarah perkembangan bahan nano 3. Klasifikasi bahan nano
- Satuan Ukuran & Skala Penskalaan Atom, Molekul, Gugus, dan Supramolekul
- Struktur dan Ikatan pada Bahan Nano Ikatan Kimia (jenis dan kekuatan) Gaya Antarmolekul Struktur Molekul dan Kristal Struktur Hierarki Transisi Massal ke Permukaan, rekonstruksi permukaan 2 Perakitan mandiri dan termodinamika
- Kimia Optik, getaran, termal Listrik Magnetik Mekanik Aspek Teoritis-mis. teori fungsional kepadatan
- Rute kimia Metode elektrokimia Pertumbuhan uap
- Metode film tipis: deposisi uap kimia, deposisi uap fisik (sputtering, ablasi laser), pertumbuhan Langmuir-Blodgett Metode mekanis: ball milling, gesekan mekanis Metode sol-gel
- Bahan nano khusus: tabung nano karbon, fullerene, kawat nano, silikon berpori Sintesis yang terinspirasi oleh bio Fabrikasi nanokomposit Nanolitografi
- Mikroskop Pemindaian dan Transmisi Elektron
- Mikroskop Pemindaian Probe: Gaya Atom, pemindaian mikroskop terowongan Teknik difraksi dan hamburan
- Spektroskopi getaran Teknik permukaan
- Nano-elektronik
- Optik nano Penginderaan kimia dan bio skala nano
- Aplikasi biologis/biomedis
- Fotovoltaik, sel bahan bakar, baterai dan aplikasi terkait energi
| - Definitions and course organization 2. Historical development of nanomaterials 3. Classification of nanomaterials
- Size & Scale Units Scaling Atoms, Molecules, Clusters and Supramolecules
- Structure and Bonding in Nanomaterials Chemical Bonds (types and strength) Intermolecular Forces Molecular and Crystalline Structures Hierarchical Structures Bulk to Surface transition, surface reconstruction 2 Self assembly and thermodynamics
- Chemical Optical, vibrational, thermal Electrical Magnetic Mechanical Theoretical Aspects-e.g. density functional theory
- Chemical routes Electrochemical methods Vapor growth
- Thin films methods: chemical vapor deposition, physical vapor deposition (sputtering, laser ablation), Langmuir-Blodgett growth Mechanical methods: ball milling, mechanical attrition Sol-gel methods
- Special nanomaterials: carbon nanotubes, fullerenes, nanowires, porous silicon Bio-inspired synthesis Nanocomposite fabrication Nanolithography
- Scanning and Transmission Electron Microscopy
- Scanning Probe Microscopies: Atomic Force, scanning tunneling microscopy Diffraction and scattering techniques
- Vibrational spectroscopy Surface techniques
- Nano-electronics
- Nano optics Nanoscale chemical- and bio-sensing
- Biological/bio-medical applications
- Photovoltaic, fuel cells, batteries and energy-related applications
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| Capaian Pembelajaran Mata Kuliah (CPMK) | - Mahasiswa mampu memehami konsep kompleks tentang teknologi nano, perancangannya, proses sintesa serta pemanfatannya
| - Students are able to understand complex concepts about nanotechnology, its design, synthesis process and use
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