1. Energy1.1 Energy, Work and Power0/01.1.1 Energy, Work and Power: Forms of Energy and Energy Transfer1.1.2 Kinetic and Potential Energy1.1.3 Work Done in Physics1.1.4 Energy Resources1.1.5 Understanding Efficiency in Energy and Power1.1.6 Power Concepts in Physics1.2 Transfer of Thermal Energy0/01.2.1 Conduction Mechanisms1.2.2 Convection Processes1.2.3 Thermal Radiation Insights1.2.4 Radiation and Temperature Equilibrium1.2.5 Radiation Experiments in Thermal Energy Transfer1.2.6 Applications of Thermal Energy Transfer1. Energy1.1 Energy, Work and Power0/01.1.1 Energy, Work and Power: Forms of Energy and Energy Transfer1.1.2 Kinetic and Potential Energy1.1.3 Work Done in Physics1.1.4 Energy Resources1.1.5 Understanding Efficiency in Energy and Power1.1.6 Power Concepts in Physics1.2 Transfer of Thermal Energy0/01.2.1 Conduction Mechanisms1.2.2 Convection Processes1.2.3 Thermal Radiation Insights1.2.4 Radiation and Temperature Equilibrium1.2.5 Radiation Experiments in Thermal Energy Transfer1.2.6 Applications of Thermal Energy Transfer2. Electricity2.1 Electrical Quantities0/02.1.1 Electric Charge2.1.2 Electric Fields2.1.3 Electric Current: The Flow of Charge2.1.4 Electromotive Force and Potential Difference2.1.5 Understanding Resistance in Electrical Circuits2.1.6 Electrical Energy and Power in Electric Circuits2.2 Electric Circuits0/02.2.1 Circuit Diagrams and Components2.2.2 Series and Parallel Circuits2.2.3 Circuit Components and Their Actions2.3 Electrical Safety0/02.3.1 Electrical Hazards2.3.2 Mains Circuits and Switches2.3.3 Safety Devices in Electrical Systems2.3.4 Appliance Safety Measures2. Electricity2.1 Electrical Quantities0/02.1.1 Electric Charge2.1.2 Electric Fields2.1.3 Electric Current: The Flow of Charge2.1.4 Electromotive Force and Potential Difference2.1.5 Understanding Resistance in Electrical Circuits2.1.6 Electrical Energy and Power in Electric Circuits2.2 Electric Circuits0/02.2.1 Circuit Diagrams and Components2.2.2 Series and Parallel Circuits2.2.3 Circuit Components and Their Actions2.3 Electrical Safety0/02.3.1 Electrical Hazards2.3.2 Mains Circuits and Switches2.3.3 Safety Devices in Electrical Systems2.3.4 Appliance Safety Measures3. Particle model of matter3.1 Density0/03.1.1 Understanding Density3.1.2 Determining Density3.1.3 Density and Buoyancy3.2 Pressure0/03.2.1 Understanding Pressure in Physics3.2.2 Pressure in Everyday Context3.2.3 Pressure in Liquids3.2.4 Calculating Pressure Changes in Liquids3.3 Kinetic Particle Model of Matter0/03.3.1 Characteristics of States of Matter3.3.2 Particle Dynamics in Different States3.3.3 Gas Behaviour and Brownian Motion3.3.4 Temperature and Pressure in Gases3.3.5 Absolute Temperature Scale and Gas Laws3.4 Thermal Properties and Temperature0/03.4.1 Characteristics of Thermal Expansion3.4.2 Particle Theory and Thermal Expansion3.4.3 Specific Heat Capacity: Theory and Formula3.4.4 Experimentation in Specific Heat Capacity3.4.5 Understanding Melting and Boiling3.4.6 Evaporation Dynamics3. Particle model of matter3.1 Density0/03.1.1 Understanding Density3.1.2 Determining Density3.1.3 Density and Buoyancy3.2 Pressure0/03.2.1 Understanding Pressure in Physics3.2.2 Pressure in Everyday Context3.2.3 Pressure in Liquids3.2.4 Calculating Pressure Changes in Liquids3.3 Kinetic Particle Model of Matter0/03.3.1 Characteristics of States of Matter3.3.2 Particle Dynamics in Different States3.3.3 Gas Behaviour and Brownian Motion3.3.4 Temperature and Pressure in Gases3.3.5 Absolute Temperature Scale and Gas Laws3.4 Thermal Properties and Temperature0/03.4.1 Characteristics of Thermal Expansion3.4.2 Particle Theory and Thermal Expansion3.4.3 Specific Heat Capacity: Theory and Formula3.4.4 Experimentation in Specific Heat Capacity3.4.5 Understanding Melting and Boiling3.4.6 Evaporation Dynamics4. Atomic structure4.1 The Nuclear Model of the Atom0/04.1.1 Fundamentals of Atomic Structure4.1.2 The Nuclear Model of the Atom: Alpha Particle Scattering Experiment4.1.3 Composition and Characteristics of the Nucleus4.1.4 Concept of Isotopes4.1.5 Nuclear Reactions: Fission and Fusion4.1.6 Proton Number and Nucleon Number Implications4.2 Radioactivity0/04.2.1 Understanding Background Radiation4.2.2 Characterizing Nuclear Emissions4.2.3 Radioactive Decay Processes4.2.4 Practical Applications of Half-life in Radioactivity4.2.5 Radioactivity in Society: Safety and Applications4. Atomic structure4.1 The Nuclear Model of the Atom0/04.1.1 Fundamentals of Atomic Structure4.1.2 The Nuclear Model of the Atom: Alpha Particle Scattering Experiment4.1.3 Composition and Characteristics of the Nucleus4.1.4 Concept of Isotopes4.1.5 Nuclear Reactions: Fission and Fusion4.1.6 Proton Number and Nucleon Number Implications4.2 Radioactivity0/04.2.1 Understanding Background Radiation4.2.2 Characterizing Nuclear Emissions4.2.3 Radioactive Decay Processes4.2.4 Practical Applications of Half-life in Radioactivity4.2.5 Radioactivity in Society: Safety and Applications5. ForcesPremium5.1 Physical Quantities and Measurement Techniques0/05.1.1 Length and Volume Measurement Techniques5.1.2 Time Measurement Strategies5.1.3 Averaging and Error Analysis in Physics5.1.4 Scalar and Vector Quantities in Physics5.1.5 Vector Addition and Resolution5.2 Motion0/05.2.1 Speed and Velocity: Essential Concepts in Motion5.2.2 Motion Representation on Graphs5.2.3 Graphs and Motion Calculations5.2.4 Acceleration Concepts in Physics5.2.5 Gravitational Motion5.3 Mass and Weight0/05.3.1 Mass vs Weight in Physics5.3.2 Gravitational Field Strength5.3.3 Measurement Techniques5.3.4 Weight and Gravity5.4 Forces0/05.4.1 Effects of Forces5.4.2 Understanding Friction5.4.3 Spring Constant and Elasticity5.4.4 Motion in Circular Paths5.4.5 Turning Effect of Forces5.4.6 Centre of Gravity in Physics5.5 Momentum0/05.5.1 Understanding Momentum in Physics5.5.2 Impulse and Momentum Change5.5.3 Conservation of Momentum5. ForcesPremium5.1 Physical Quantities and Measurement Techniques0/05.1.1 Length and Volume Measurement Techniques5.1.2 Time Measurement Strategies5.1.3 Averaging and Error Analysis in Physics5.1.4 Scalar and Vector Quantities in Physics5.1.5 Vector Addition and Resolution5.2 Motion0/05.2.1 Speed and Velocity: Essential Concepts in Motion5.2.2 Motion Representation on Graphs5.2.3 Graphs and Motion Calculations5.2.4 Acceleration Concepts in Physics5.2.5 Gravitational Motion5.3 Mass and Weight0/05.3.1 Mass vs Weight in Physics5.3.2 Gravitational Field Strength5.3.3 Measurement Techniques5.3.4 Weight and Gravity5.4 Forces0/05.4.1 Effects of Forces5.4.2 Understanding Friction5.4.3 Spring Constant and Elasticity5.4.4 Motion in Circular Paths5.4.5 Turning Effect of Forces5.4.6 Centre of Gravity in Physics5.5 Momentum0/05.5.1 Understanding Momentum in Physics5.5.2 Impulse and Momentum Change5.5.3 Conservation of Momentum6. WavesPremium6.1 General Properties of Waves0/06.1.1 Energy Transfer in Waves6.1.2 General Properties of Waves: Wave Features and Terminology6.1.3 Types of Waves6.1.4 Wave Behavior and Interactions6.1.5 Utilizing Ripple Tanks in Wave Studies6.1.6 Exploring Diffraction6.2 Light0/06.2.1 Reflection of Light6.2.2 Refraction of Light6.2.3 Thin Lenses in Physics6.2.4 Dispersion of Light6.3 Electromagnetic Spectrum0/06.3.1 Electromagnetic Spectrum Overview6.3.2 Electromagnetic Spectrum: Uses and Effects of Electromagnetic Waves6.3.3 Digital and Analogue Signals6.4 Sound0/06.4.1 Production and Nature of Sound6.4.2 Human Auditory Range6.4.3 Medium for Sound Transmission6.4.4 Speed of Sound in Different Mediums6.4.5 Sound Characteristics6.4.6 Ultrasound: Exploring High-Frequency Sound Waves Beyond Human Hearing6. WavesPremium6.1 General Properties of Waves0/06.1.1 Energy Transfer in Waves6.1.2 General Properties of Waves: Wave Features and Terminology6.1.3 Types of Waves6.1.4 Wave Behavior and Interactions6.1.5 Utilizing Ripple Tanks in Wave Studies6.1.6 Exploring Diffraction6.2 Light0/06.2.1 Reflection of Light6.2.2 Refraction of Light6.2.3 Thin Lenses in Physics6.2.4 Dispersion of Light6.3 Electromagnetic Spectrum0/06.3.1 Electromagnetic Spectrum Overview6.3.2 Electromagnetic Spectrum: Uses and Effects of Electromagnetic Waves6.3.3 Digital and Analogue Signals6.4 Sound0/06.4.1 Production and Nature of Sound6.4.2 Human Auditory Range6.4.3 Medium for Sound Transmission6.4.4 Speed of Sound in Different Mediums6.4.5 Sound Characteristics6.4.6 Ultrasound: Exploring High-Frequency Sound Waves Beyond Human Hearing7. Magnetism and electromagnetismPremium7.1 Simple Phenomena of Magnetism0/07.1.1 Magnetic Forces and Poles7.1.2 Induced Magnetism7.1.3 Types of Magnets7.1.4 Magnetic Fields7.1.5 Applications of Magnets7.2 Electromagnetic Effects0/07.2.1 Fundamentals of Electromagnetic Induction7.2.2 Practical Applications of Induction7.2.3 A.C. Generator Mechanics and Outputs7.2.4 Magnetic Influence of Electric Currents7.2.5 Interactions in Magnetic Fields7.2.6 Dynamics of D.C. Motors7.2.7 Transformer Technology7. Magnetism and electromagnetismPremium7.1 Simple Phenomena of Magnetism0/07.1.1 Magnetic Forces and Poles7.1.2 Induced Magnetism7.1.3 Types of Magnets7.1.4 Magnetic Fields7.1.5 Applications of Magnets7.2 Electromagnetic Effects0/07.2.1 Fundamentals of Electromagnetic Induction7.2.2 Practical Applications of Induction7.2.3 A.C. Generator Mechanics and Outputs7.2.4 Magnetic Influence of Electric Currents7.2.5 Interactions in Magnetic Fields7.2.6 Dynamics of D.C. Motors7.2.7 Transformer Technology8. Space physicsPremium8.1 Earth and the Solar System0/08.1.1 Earth's Rotational Dynamics8.1.2 Earth's Orbital Characteristics8.1.3 Lunar Orbit and Phases8.1.4 Calculating Orbital Speed8.1.5 Composition of the Solar System8.1.6 Planetary Types and Accretion Theory8.1.7 Gravitational Influence of Planets8.1.8 Light Travel Time in the Solar System8.1.9 The Sun's Gravitational Role in the Solar System8.1.10 Elliptical Planetary Orbits8.2 Stars and the Universe0/08.2.1 Characteristics of the Sun8.2.2 Nuclear Fusion in Stars8.2.3 Structure of Galaxies8.2.4 The Life Cycle of Stars8.2.5 The Expanding Universe8.2.6 Cosmic Microwave Background Radiation (CMBR)8.2.7 Galactic Motion and Redshift8.2.8 The Hubble Constant and Estimating Universe's Age8. Space physicsPremium8.1 Earth and the Solar System0/08.1.1 Earth's Rotational Dynamics8.1.2 Earth's Orbital Characteristics8.1.3 Lunar Orbit and Phases8.1.4 Calculating Orbital Speed8.1.5 Composition of the Solar System8.1.6 Planetary Types and Accretion Theory8.1.7 Gravitational Influence of Planets8.1.8 Light Travel Time in the Solar System8.1.9 The Sun's Gravitational Role in the Solar System8.1.10 Elliptical Planetary Orbits8.2 Stars and the Universe0/08.2.1 Characteristics of the Sun8.2.2 Nuclear Fusion in Stars8.2.3 Structure of Galaxies8.2.4 The Life Cycle of Stars8.2.5 The Expanding Universe8.2.6 Cosmic Microwave Background Radiation (CMBR)8.2.7 Galactic Motion and Redshift8.2.8 The Hubble Constant and Estimating Universe's Age