Gasal 2021/2022
Kelas-Offr:
MD-MBKM
Deskripsi:
Coulomb’s Law: Coulomb’s Law, Charge Is Quantized, Charge Is Conserved. Electric Fields: The Electric Field, The Electric Field Due to A Charged Particle, The Electric Field Due to A Dipole, The Electric Field Due to A Line of Charge, The Electric Field Due to A Charged Disk, A Point Charge in An Electric Field, A Dipole In An Electric Field. Gauss’ Law: Electric Flux, Gauss’ Law, A Charged Isolated Conductor, Applying Gauss’ Law: Cylindrical Symmetry, Applying Gauss’ Law: Planar Symmetry, Applying Gauss’ Law: Spherical Symmetry. Electric Potential: Electric Potential, Equipotential Surfaces and The Electric Field, Potential Due to A Charged Particle, Potential Due to An Electric Dipole, Potential Due to A Continuous Charge Distribution, Calculating the Field from The Potential, Electric Potential Energy of a System Of, Potential Of A Charged Isolated Conductor. Capacitance: Capacitance, Calculating the Capacitance, Capacitors in Parallel and In Series, 25-4 Energy Stored in An Electric Field, 25-5 Capacitor with A Dielectric, 25-6 Dielectrics And Gauss’ Law. Current and Resistance: 26-1 Electric Current, 26-2 Current Density, 26-3 Resistance and Resistivity, 26-4 Ohm’s Law, 26-5 Power, Semiconductors, Superconductors. Circuits: 27-1 Single-Loop Circuits, 27-2 Multiloop Circuits, 27-3 The Ammeter and The Voltmeter, 27-4 RC Circuits. Magnetic Fields: 28-1 Magnetic Fields and The Definition Of, 28-2 Crossed Fields: Discovery of The Electron, 28-3 Crossed Fields: The Hall Effect, 28-4 A Circulating Charged Particle, 28-5 Cyclotrons And Synchrotrons, 28-6 Magnetic Force On A Current-Carrying Wire, 28-7 Torque On A Current Loop, 28-8 The Magnetic Dipole Moment. Magnetic Fields Due to Currents: 29-1 Magnetic Field Due To A Current, 29-2 Force Between Two Parallel Currents, 29-3 Ampere’s Law, 29-4 Solenoids and Toroids, 29-5 A Current-Carrying Coil As A Magnetic Dipole. Induction and Inductance: 30-1 Faraday’s Law And Lenz’s Law, 30-2 Induction And Energy Transfers, 30-3 Induced Electric Fields, 30-4 Inductors And Inductance, 30-5 Self-Induction, 30-6 RL Circuits, 30-7 Energy Stored In A Magnetic Field, 30-8 Energy Density Of A Magnetic Field, 30-9 Mutual Induction. Electromagnetic Oscillations And Alternating Current: 31-1 LC Oscillations, 31-2 Damped Oscillations In An RLC Circuit, 31-3 Forced Oscillations Of Three Simple Circuits, 31-4 The Series RLC Circuit, 31-5 Power In Alternating-Current Circuits, 31-6 Transformers. Gejala kemagnetan: gaya& medan magnet, gaya pada muatan listrik dalam medan magnet, penghantar berarus listrik pada medan magnet, torka pada loop listrik dalam medan magnet, effek Hall. Sumber medan magnet: hukum Biot-Savart dan gaya magnet pada dua konduktor sejajar berarus lisrik, hukum Ampere, medan magnet oleh solenoida, hukum Gauss pada kemagnetan, kemagnetan dalam bahan. Hukum Faraday & Lenz: Induksi magnetik, medan magnet induksi, generator & motor listrik, arus Eddy. Iduktansi: induksi diri dan nduktansi, rangkain R-L, energi dalam medan magnet, induktansi bersama, rangkaian LC & RLC. Rangkaian AC: Sumber arus AC, hambatan, induktor, dan kapasitor dalam rangkaian AC, daya dalam rangkaian AC, resonansi dalam rangkaian RLC, penyearah dan filter, transformator dan transmisi daya. Gelombang EM: arus pergeseran dan hukum Ampere, persamaan Maxwell, gelombang EM bidang, energi yang dibawa gelombang EM, momentum dan daya radiasi, antena, spektrum gelombang EM. Optika Geometri: sifat-sifat cahaya, pemantulan & pembiasan cahaya, pemantulan total, dispersi, pembentukan bayangan pada cermin dan lensa, alat-alat optic. Optika gelombang, interferensi: percobaan Young & interferensi cahaya, perubahan fase akibat pemantulan, interfensi cahaya pada selaput tipis, interferometer Michelson. Optika gelombang, difraksi & polarisasi: difraksi oleh & resolusi celah tunggal, difraksi oleh celah ganda, difraksi oleh kisi, difraksi sinar X pada kristal, polarisasi cahaya. Teori Relativitas: Mekanika klasik & kovariansi Galileo, percobaan Michelson–Morley & keabsolutan kecepatan cahaya, postulat relativitas khusus Einstein, transformasi Lorentz. Konsekuensi teori relativitas khusus: dilasi waktu, kontraksi panjang, paradoks kembar, massa& mometum relativistik, kemanunggalan massa & energi. Teori relativitas umum: kesetaraan massa gravitasional dengan massa inersial dan konsekuensinya pada penyetaraan kerangka inersial & non inersial, asan kovariansi umum hukum alam.Pengantar Fisika Kuantum: Radiasi benda hitam & postulat Planck, efek fotolistrik & watak partikel cahaya, hipotesis deBroglie, ketakpastian Heisenberg.
Capaian Pembelajaran
Menguasai konsep-konsep esensial kemagnetan, induktansi, rangkaian AC, gelombang elektromagnet, dan optika; dan mampu menjelaskan secara ilmiah fenomena alam dan produk teknologi dalam kehidupan sehari-hari yang berhubungan dengan konsep-konsep tersebut.
Memahami konsep-konsep esensial teori relativitas khusus dan fisika kuantum beserta pemikiran yang melandasi lahirnya teori relativitas khusus dan fisika kuantum sebagai pilar fisika modern; dan menyadari bahwa fisika merupakan ilmu terus berkembang.
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- Teacher: Hari Wisodo