Studied by 5 peopleEquation for Magnification
magnification = size of image / size of real object
Equation for Photosynthesis
carbon dioxide + water —(Light)→ oxygen + glucose
Equation for aerobic respiration
oxygen + glucose → carbon dioxide + water
Equation for anaerobic respiration (animals)
glucose → lactic acid
Equation for anaerobic respiration (plants)
glucose → ethanol + carbon dioxide
Avogadro constant
6.02 x 10^23
Equation from mean rate or reaction
mean rate of reaction = quantity of reactant used / time taken
mean rate of reaction = quantity of product formed /time taken
Equation for a reversible reaction
A + B ⇌ C + D
Equation for alkanes
Equation for Retardation factor
Retardation factor = distance moved by substance distance moved by solvent
Equation for kinetic energy
kinetic energy = 0.5 × mass × speed^2
kinetic energy (Ek) - joules (J) mass(m) - kilograms (kg) speed (v) - metres per second (m/s)
Equation for elastic potential energy
elastic potential energy = 0.5 × spring constant × (extension)^2
elastic potential energy (Ee) - joules (J) spring constant (k)- newtons per metre (N/m) extension (e) - metres (m)
Equation for gravitational potential energy
g. p. e. = mass × gravitational field strength × height
gravitational potential energy (Ep) - joules (J) mass (m) - kilograms (kg) gravitational field strength (g) - newtons per kilogram (N/kg) height (h) - metres (m)
Equation for Thermal Energy
change in thermal energy = mass × specific heat capacity × temperature change
change in thermal energy (∆E) - joules (J) mass (m) - kilograms (kg) specific heat capacity (c) - joules per kilogram per degree Celsius (J/kg °C) temperature change (∆θ) - degrees Celsius (°C)
Equation for power
power = energy transferred / time
power = work done / time
power (P) - watts (W) energy transferred (E) - joules (J) time (t) - seconds (s) work done (W) - joules (J)
Equation for efficiency
efficiency = useful output energy transfer / total in put energy transfer
efficiency = useful power output / total power input
Equation for charge flow
charge flow = current × time
charge flow (Q) - coulombs (C) current (I) - amperes/amps (A time (t) - seconds (s)
Equation for potential difference
potential difference = current × resistance
potential difference (V) - volts (V) current (I) - amperes/amps (A) resistance (R) - ohms (Ω)
Equation for total resistance
resistance (R) - ohms (Ω)
Equation for power
power = potential difference × current
power = current^2 × resistance
power (P) - watts (W) potential difference (V) - volts (V) current (I) - amperes/amps (A) resistance (R) - ohms (Ω)
Equation for energy transferred
energy transferred = power × time
energy transferred = charge flow × potential difference
power (P) - watts (W) time (t) - seconds (s) charge flow (Q) - coulombs (C) potential difference (V) - volts (V)
Equation for density
density = mass / volume
density (ρ) - kilograms per metre cubed (kg/m^3) mass (m) - kilograms (kg) volume (V) - metres cubed (m^3)
Equation for energy change (state change)
energy for a change of state = mass × specific latent heat
energy (E) - joules (J) mass (m) - kilograms (kg) specific latent heat (L) - joules per kilogram (J/kg)
Equation for weight
weight = mass × gravitational field strength
weight (W) - newtons (N) mass (m) - kilograms (kg) gravitational field strength (g) - newtons per kilogram (N/kg)
Equation of Work done
work done = force × distance
work done (W) - joules (J) force (F) - newtons (N) distance (s) - metres (m)
Equation of force (1)
force = spring constant × extension
force (F) -newtons (N) spring constant (k) - newtons per metre (N/m) extension (e) - metres (m)
Equation of distance travelled
distance travelled = s peed × time
distance (s) - metres (m) speed (v) - metres per second (m/s) time (t) - seconds (s)
Equation of acceleration
acceleration = change in velocity / time taken
acceleration (a) - metres per second squared (m/s^2) change in velocity (∆v) - metres per second (m/s) time (t) - seconds (s)
Equation of acceleration (different)
final velocity 2 − initial velocity 2 = 2 × acceleration × distance
final velocity (v) - metres per second (m/s) initial velocity u) - metres per second (m/s) acceleration (a) - metres per second squared (m/s^2) distance (s) - metres (m)
Equation of resultant force
resultant force = mass × acceleration
force (F) - newtons (N) mass (m) - kilograms (kg) acceleration (a) - metres per second squared (m/s^2)
Equation of momentum
momentum = mass × velocity
momentum (p) - kilograms metre per second (kg m/s) mass (m) - kilograms (kg) velocity (v) - metres per second (m/s)
Equation of period
period = 1 / frequency
period (T) - seconds (s) frequency (f) - hertz (Hz)
Equation of wave speed
wave speed = frequency × wavelength
wave speed (v) - metres per second (m/s) frequency (f) - hertz (Hz) wavelength (λ) - metres (m)
Equation of force (2)
force = magnetic flux density × current × length
force (F) - newtons (N) magnetic flux density (B) - tesla (T) current (I) - amperes/amps (A) length (/) - metres (m)
Note
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