Igcse physics formula
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This document provides important equations in physics for the IGCSE course. It covers general physics topics like motion, forces, energy, waves, light, sound, electricity and magnetism. Some key equations included are: - Velocity (v) = Distance (s) / Time (t) - Acceleration (a) = Change in Velocity (v - u) / Time (t) - Hooke's Law: Force (F) = Spring Constant (k) x Extension (x) - Kinetic Energy (Ek) = 1/2 x Mass (m) x Velocity (v)^2 - Refractive Index (n) = Speed of light in first medium / Speed of light
Igcse physics formula
- 1. Important Equations in Physics for IGCSE course General Physics: 1 For constant motion: ݒ = ݏ ݐ ‘v’ is the velocity in m/s, ‘s’ is the distance or displacement in meters and ‘t’ is the time in sec 2 For acceleration ‘a’ ܽ = ݒ − ݑ ݐ u is the initial velocity, v is the final velocity and t is the time 3 Graph: in velocity-time graph the area under the graph is the total distance covered Area of a rectangular shaped graph = base × height Area of triangular shaped graph = ½ × base × height 4 Weight is the force of gravity and mass is the amount of matter ݓ = ݉ × ݃ w is the weight in newton (N), m is the mass in kg and g is acceleration due to gravity = 10 m/s2 5 Density ‘ρ’ in kg/m3 (ρ is the rhoo) ߩ = ݉ ܸ m is the mass and V is the volume 6 Force F in newtons (N) ܨ = ݉ × ܽ m is the mass and a is acceleration 7 Terminal Velocity: falling with air resistance ܹ݁݅݃ℎݐ ݂ ܽ݊ ܾ݆݁ܿݐ(݀ݓ݊ݓܽݎ݀) = ܽ݅ݎ ݎ݁ݏ݅ݏݐܽ݊ܿ݁ (ݑݓܽݎ݀ݏ) implies no net force, therefore no acceleration, constant velocity 8 Hooke’s Law ܨ = ݇ × ݔ F is the force, x is the extension in meters and k is the spring constant 9 Moment of a force in N.m (also turning effect) ݉݉݁݊ݐ ݂ ݂ݎܿ݁ = ܨ × ݀ d is the perpendicular distance from the pivot and F is the force 10 Law of moment or equilibrium ܶݐ݈ܽ ݈ܿܿ݇ݓ݅ݏ݁ ݉݉݁݊ݐ = ݐݐ݈ܽ ܽ݊ݐ݈݅ܿܿ݇ݓ݅ݏ݁ ݉݉݁݊ݐ => ܨଵ × ݀ଵ = ܨଶ × ݀ଶ 11 Conditions of Equilibrium Net force on x-axis=zero, net force on y-axis= zero, net moment=zero 11 Work done W joules (J) ܹ = ܨ × ݀ F is the force and d is the distance covered by an object same direction 12 Kinetic Energy Ek in joules (J) ܧ = 1 2 × ݉ × ݒଶ m is the mass(kg) and v is the velocity (m/s) 13 Potential Energy ΔEp in joules (J) Δܧ = ݉ × ݃ × Δℎ m is mass (kg) and g is gravity and Δh is the height from the ground 14 Law of conservation of energy: ܮݏݏ ݂ ܧ = ݃ܽ݅݊ ݂ ܧ ݉ × ݃ × ℎ = 1 2 × ݉ × ݒଶ 15 Power in watts (W) ܲ = ݓݎ݇ ݀݊݁ ݐ݅݉݁ ݐܽ݇݁݊ ܲ = ܧ݊݁ݎ݃ݕ ݎܽ݊ݏ݂݁ݎ ݐ݅݉݁ ݐܽ݇݁݊ Power is the rate of doing work or rate of transferring the energy from one form to another 16 Efficiency: ܧ݂݂݅ܿ݅݁݊ܿݕ = ݑݏ݂݁ݑ݈ ݑݐݑݐ ݐݐ݈ܽ ݁݊݁ݎ݃ݕ ݅݊ݑݐ × 100 17 Pressure p in pascal (Pa) = ܨ ܣ F is the force in newton (N) and A is the area in m2 18 Pressure p due to liquid = ߩ × ݃ × ℎ ρ is the density in kg/m3, h is the height or depth of liquid in meters and g is the gravity 19 Atmospheric pressure P=760mmHg = 76cm Hg =1.01x105Pa 20 Energy source renewable can be reused non-renewable cannot be reused Hydroelectric eg dam, waterfall Chemical energy eg petrol, gas Geothermal eg from earth’s rock Nuclear fission eg from uranium Solar eg with solar cell Wind energy eg wind power station Tidal/wave energy eg tide in ocean
- 2. Thermal Physics: 1 Boyle’s law: Pressure and volume are inversely proportional ∝ ܸ pV=constant ଵ × ܸଵ = ଶ × ܸଶ p1 and p2 are the two pressures in Pa and V1 and V2 are the two volumes in m3 2 Thermal Expansion (Linear) L = ×Lo × Lo is the original length in meters, is the change in temperature in oC, L is the change in length in meters (L1- Lo) and is the linear expansivity of the material 3 Thermal Expansion (Cubical) V = Vo = 3 Vo is the original volume in m3, is the change in temperature in oC,V is the change in volume in m3 (V1- Vo) and is the cubical expansivity of the material. 4 Charle’s Law: Volume is directly proportional to absolute temperature ܸ ∝ ܶ ܸ ܶ = ܿ݊ݏݐܽ݊ݐ ܸଵ ܸଶ = ܶଵ ܶଶ V is the volume in m3 and T is the temperature in kelvin (K). 5 Pressure Law: Pressure of gas is directly proportional to the absolute temperature ∝ ܶ ܶ = ܿ݊ݏݐܽ݊ݐ ଵ ଶ = ܶଵ ܶଶ p is the pressure in Pa and T is the temperature in Kelvin (K). 6 Gas Law (combining above laws) ܸ ܶ = ܿ݊ݏݐܽ݊ݐ ଵܸଵ ܶଵ = ଶܸଶ ܶଶ In thermal physics the symbol θ is used for celsius scale and T is used for kelvin scale. 7 Specific Heat Capacity: Amount of heat energy required to raise the temperature of 1 kg mass by 1oC. ܿ = ܳ ݉ × Δߠ c is the specific heat capacity in J/(kg oC), Q is the heat energy supplied in joules (J), m is the mass in kg and Δθ is the change in temperature 8 Thermal Capacity: amount of heat require to raise the temperature of a substance of any mass by 1oC Thermal capacity=m×c ܶℎ݁ݎ݈݉ܽ ܿܽܽܿ݅ݐݕ = ܳ Δߠ The unit of thermal capacity is J/oC. 9 Specific latent heat of fusion (from solid to liquid) ܮ = ܳ ݉ Lf is the specific latent heat of fusion in J/kg or J/g, Q is the total heat in joules (J), m is the mass of liquid change from solid in kg or g. 10 Specific latent heat of vaporization (from liquid to vapour) ܮ௩ = ܳ ݉ Lv is the specific latent heat of vaporization in J/kg or J/g, Q is the total heat in joules (J), m is the mass of vapour change from liquid in kg or g. 11 Thermal or heat transfer In solid = conduction In liquid and gas = convection and also convection current (hot matter goes up and cold matter comes down) In vacuum = radiation 12 Emitters and Radiators Dull black surface = good emitter, good radiator, bad reflector Bright shiny surface = poor emitter, poor radiator, good reflector 13 Another name for heat radiation Infrared radiation or radiant heat 14 Melting point Change solid into liquid, energy weaken t he molecular bond, no change in temperature, molecules move around each other 15 Boiling point Change liquid into gas, energy break molecular bond and molecules escape the liquid, average kinetic energy increase, no change in temperature, molecule are free to move 16 Condensation Change gas to liquid, energy release, bonds become stronger 17 Solidification Change liquid to solid, energy release bonds become very strong 18 Evaporation Change liquid to gas at any temperature, temperature of liquid decreases, happens only at the surface
- 3. Waves, light and sound: 1 Wave motion Transfer of energy from one place to another 2 Frequency f Number of cycle or waves in one second, unit hertz (Hz) 3 Wavelength λ Length of one complete waves, unit, meters (m) 4 Amplitude a Maximum displacement of medium from its mean position, meters 5 wavef ront A line on which the disturbance of all the particles are at same point from the central position eg a crest of a wave is a wavefront 6 Wave equation 1 ݒ = ݂ × ߣ v is the speed of wave in m/s, f is the frequency in (hertz) Hz, λ is the wavelength in meters 7 Wave equation 2 ݂ = 1 ܶ T is the time period of wave in seconds 8 Movement of particles of the medium Longitudinal waves=> back and forth parallel to the direction of the waves Transverse waves=> perpendicular to the direction of the waves 9 Law of reflection Angle of incidence i = angel of reflection ݈ܽ݊݃݁ ݅ = ݈ܽ݊݃݁ ݎ 10 Refraction From lighter to denser medium → light bend towards the normal From denser to lighter medium → light bend away from the normal 11 Refractive index n (Refractive index has not units) ݊௦௦ = ݏ݅݊ ∠݅ ௩௨௨ ݏ݅݊ ∠ݎ௦௦ ݊௦௦ = ݏ݁݁݀ ݂ ݈݅݃ℎݐ ݅݊ ܽ݅ݎ ݎ ݒܽܿݑݑ݉ ݏ݁݁݀ ݂ ݈݅݃ℎݐ ݅݊ ݈݃ܽݏݏ 12 Diffraction Bending of waves around the edges of a hard surface 13 Dispersion Separation of different waves according to colours or frequency for example by using prism 14 Image from a plane mirror Virtual, upright, same size and laterally inverted and same distance from the mirror inside 15 Image from a convex lens When close: virtual, enlarge, upright When far: real, small, upside down 16 Image from a concave lens Virtual, upright, small 17 Critical angle When light goes from denser to lighter medium, the incident angle at whi ch t he refl ect ed angl e i s 90o, is called critical angle. 18 Total internal reflection (TIR) When light goes from denser to lighter medium, the refracted ray bend inside the same medium called (TIR) eg optical fibre 19 Electromagnetic Spectrum: travel in vacuum, oscillating electric and magnetic fields ←λ (decrease) and f (increase) λ (increases) and f (decrease)→ Gammas X-Rays Ulra violet Visible Infrared Micro rays rays (light) rays rays waves Radio waves 20 Gamma rays: for killing cancer cells X-rays: in medicine UV rays: for sun tan and sterilization of medical instruments Visible light: light rays, monochromatic means one colour Infrared: remote controls, treatment of muscular pain Micro waves: international communication, mobile phones Radio waves: radio and television communication 21 Colours of visible light VIBGYO R wavelengths Violet 4×10-7m Indigo Blue Green Yellow Orange Red 7×10-7m 22 Speed of light waves or electromagnetic waves In air: 3×108m/s In water: 2.25×108m/s In glass: 2×108m/s 23 Light wave Transverse electromagnetic waves 24 Sound wave are longitudinal waves particles of the medium come close to each other → compression particles of the medium move away → rarefaction 25 Echo ݒ = 2 × ݀ ݐ v is the speed of sound waves, d is the distance in meters between source and the reflection surface and t is the time for echo 26 Properties of sound waves Pitch is similar to the frequency of the wave Loudness is similar to the amplitude of the wave 27 Speed of sound waves Air : 330-340 m/s Water: 1400 m/s Concrete : 5000 m/s Steel: 6000–7000 m/s
- 4. Electricity and magnetism: 1 Ferrous Materials Attracted by magnet and can be magnetized iron, steel, nickel and cobalt (iron temporary and steel permanent) 2 Non-ferrous materials Not attracted by magnet and cannot be magnetized copper, silver, aluminum, wood, glass 3 Electric field The space or region around a charge where a unit charge experience force Direction is outward from positive charge and inward into negative charge 4 Electric field intensity Amount force exerted by the charge on a unit charge (q) placed at a point in the field E is the electric field intensity in N/C ܧ = ܨ ݍ 5 Current (I): Rate of flow of charges in conductor ܫ = ܳ ݐ I is the current in amperes (A), Q is the charge in coulombs (C) t is the time in seconds (s) 6 Current In circuits the current always choose the easiest path 7 Ohms law Voltage across the resistor is directly proportional to current, V⋉ I provided if the physical conditions remains same ூ = ܴ V is the voltage in volts (V), I is the current in amperes (A) and R is resistance in ohms (Ω) 8 Voltage (potential difference) Energy per unit charge ܸ = ܧ݊݁ ݃ݕ ܿℎܽݎ ݁ = ܧ ݍ q is the charge in coulombs (C), V is the voltage in volts (V) Energy is in joules (J) 9 E.M.F. Electromotive force E.M.F. = lost volts inside the power source + terminal potential difference EMF=Ir+IR 10 Resistance and resistivity ܴ = ߩ ܮ ܣ ρ is the resistivity of resistor in Ω.m R is the resistance a resistor, L is the length of a resistor in meters A is the area of cross-section of a resistor in m2 11 Circuit In series circuit→ the current stays the same and voltage divides In parallel circuit → the voltage stays the same and current divides 12 Resistance in series ܴ = ܴଵ + ܴଶ + ܴଷ R, R1, R2 and R3 are resistances of 13 Resistance in parallel resistors in ohms 1 ܴ = 1 ܴଵ + 1 ଶ + 1 ܴଷ 14 Potential divider or potentiometer ܸଵ ଶ = ܴଵ ଶ ܴଶ ܴଵ + ܴଶ 15 Potential divider ܸଶ = ( ܴଵ ܴଵ + ܴଶ ) × ܸ ܸଵ = ( ) × ܸ 16 Power ܲ = ܫ × ܸ ܲ = ܫଶ × ܴ ܲ = ܸଶ ܴ P is the power in watts (W) 17 Power ܲ = ܧ݊݁ݎ݃ݕ ݐ݅݉݁ The unit of energy is joules (J) 18 Diode Semiconductor device... current pass only in one direction, rectifier 19 Transistor Semiconductor device works as a switch , collector, base, emitter 20 Light dependent resistor LED resistor depend upon light, brightness increases the resistance decrease 21 Thermistor Resistor depend upon temperature, temperature increase resistance decrease 22 Capacitor Parallel conductor with insulator in between to store charges 23 Relay Electromagnetic switching device 24 Fleming’s RH or LH rule thuMb Direction of motion First finger Direction of magnetic field seCond finger Direction of current 25 Transformer ܸ௦ = ݊௦ Vp and Vs are the voltages; np and ns are the no of turns in primary and secondary coils
- 5. 26 Transformer ܲ ܲ௦ ܫ × ܸ = ܫ௦ × ܸ௦ ܸ௦ = ܫ Power in primary coil =Power in secondary coil Ip and Is the currents in primary and secondary coil 27 E.M induction Emf or current is induced in a conductor when it cuts the magnetic field lines 28 a.c. generator Produce current, use Fleming’s right hand rule 29 d.c. motor Consume current, use Fleming’s left hand rule 30 Logic Gates AND Gate OR Gate NOT Gate NAND Gate NOR Gate 1 2 out 1 2 out in out 1 2 out 1 2 out 0 0 0 0 0 0 0 1 0 0 1 0 0 1 0 1 0 0 1 1 1 0 0 1 1 0 1 0 1 0 0 1 0 1 1 0 1 1 0 0 1 1 1 1 1 1 1 1 0 1 1 0 31 Cathode rays Stream of electrons emitted from heated metal (cathode). This process is called thermionic emission. 32 CRO Horizontal or y-plates for vertical movement of electron beam Timebase or x-plates for horizontal movement Atomic Physics: 1 Alpha particles α-particles Double positive charge Helium nucleus Stopped by paper Highest ionization potential 2 Beta-particles β-particles Single negative charge Fast moving electrons Stopped by aluminum Less ionization potential 3 Gamma-particles γ-rays No charge Electromagnetic radiation Only stopped by thick a sheet of lead Least ionization potential 4 Half-life Time in which the activity or mass of substance becomes half 5 Atomic symbol ܺ A is the total no of protons and neutrons Z is the total no of protons 6 Isotopes Same number of protons but different number of neutrons