AP Physics C Thermodynamics Equations

AP Physics C:
Thermodynamics

EQUATIONS

INFORMATION

Fahrenheit - Celsius Relationship

$Fahrenheit - Celsius Relationship$

$\\ \bold{T_F} = temperature \hspace{4} (^\circ F) \\ \bold{T_C} = temperature \hspace{4} (^\circ C) \\$

Kelvin - Celsius Relationship

$Kelvin - Celsius Relationship$

$\\ \bold{T_K} = temperature \hspace{4} (K) \\ \bold{T_C} = temperature \hspace{4} (^\circ C)$

Kelvin - Fahrenheit Relationship

$Kelvin - Fahrenheit Relationship$

$\\ \bold{T_K} = temperature \hspace{4} (K) \\ \bold{T_F} = temperature \hspace{4} (^\circ F)$

Boyle's Law

$Boyle's Law$

$\\ \bold{P} = pressure \hspace{4} of \hspace{4} the \hspace{4} system \hspace{4} (N \hspace{2} m^{-2}) \\ \bold{V} = volume \hspace{4} of \hspace{4} the \hspace{4} gas \hspace{4} (m^3) \\ \bold{k} = constant \hspace{4} value \hspace{4} (N \hspace{2} m)$

Charles' Law

$Charles' Law$

$\\ \bold{V} = volume \hspace{4} of \hspace{4} gas \hspace{4} (m^3) \\ \bold{T} = temperature \hspace{4} of \hspace{4} gas \hspace{4} (K) \\ \bold{k} = constant \hspace{4} value (m^3 \hspace{2} K^{-1})$

Gay-Lussac's Law

$Gay-Lussac's Law$

$\\ \bold{P} = pressure \hspace{4} of \hspace{4} system \hspace{4} (N \hspace{2} m^{-2}) \\ \bold{T} = temperature \hspace{4} of \hspace{4} the \hspace{4} gas \hspace{4} (K) \\ \bold{k} = constant \hspace{4} value \hspace{4} (N \hspace{2} m^{-2} \hspace{2} K)$

Combined Gas Law

$Combined Gas Law$

$\\ \bold{P_\&hash;} = pressure \hspace{4} of \hspace{4} system \hspace{4} \&hash; \hspace{4} (N \hspace{2} m^{-2}) \\ \bold{V_\&hash;} = volume \hspace{4} of \hspace{4} gas \hspace{4} \&hash; \hspace{4} (m^3) \\ \bold{T_\&hash;} = temperature \hspace{4} of \hspace{4} gas \hspace{4} \&hash; \hspace{4} (K) \\ \bold{k} = constant \hspace{4} value \hspace{4} (N \hspace{4} m \hspace{4} K^{-1})$

Ideal Gas Law

$Ideal Gas Law$

$\\ \bold{P} = pressure \hspace{4} (Pa) \\ \bold{V} = volume \hspace{4} (m^3) \\ \bold{n} = number \hspace{4} of \hspace{4} moles \hspace{4} of \hspace{4} gas \hspace{4} (mol)\\ \bold{R} = gas \hspace{4} constant \hspace{4} (8.314 \hspace{2} J \hspace{2} K^{-1} \hspace{4} mol^{-1}) \\ \bold{T} = temperature \hspace{4} (K) \\ \bold{N} = number \hspace{4} of \hspace{4} particles\\ \bold{k} = Boltzmann \hspace{4} constant \\ \indent \hspace{5} (1.38 \hspace{2} x 10^{-23} \hspace{2} m^2 \hspace{2} kg \hspace{2} s^{-2} \hspace{2} K^{-1}) \\$

Thermal Expansion (Solids)

$Thermal Expansion (Solid)$

$\\ \bold{\Delta L} = change \hspace{4} in \hspace{4} length \hspace{4} (m) \\ \bold{\alpha} = average \hspace{4} coefficient \hspace{4} of \hspace{4} linear \\ \indent \hspace{6} expansion \hspace{4} (K^{-1}) \\ \bold{L_i} = initial \hspace{4} length \hspace{4} (m) \\ \bold{\Delta T} = change \hspace{4} in \hspace{4} temperature \hspace{4} (K)$

Thermal Expansion (Liquids and Gases)

$Thermal Expansion (Liquids and Gases)$

$\\ \bold{\Delta V} = change \hspace{4} in \hspace{4} volume \hspace{4} (m^3) \\ \bold{\beta} = average \hspace{4} coefficient \hspace{4} of \hspace{4} volume \\ \indent \hspace{6} expansion \hspace{4} (K^{-1}) \\ \bold{V_i} = initial \hspace{4} volume \hspace{4} (m^3) \\ \bold{\Delta T} = change \hspace{4} in \hspace{4} temperature \hspace{4} (K)$

Heat

$Heat$

$\\ \bold{Q} = heat \hspace{4} (J) \\ \bold{m} = mass \hspace{4} (kg) \\ \bold{c} = specific \hspace{4} heat \hspace{4} capacity \hspace{4} (J \hspace{2} kg^{-1} \hspace{4} K^{-1}) \\ \bold{\Delta T} = change \hspace{4} in \hspace{4} temperature \hspace{4} (K) \\ \bold{H_f} = heat \hspace{4} of \hspace{4} fusion \hspace{4} (J \hspace{2} kg^{-1}) \\ \bold{H_v} = heat \hspace{4} of \hspace{4} vaporization \hspace{4} (J \hspace{2} kg^{-1})$

Latent Heat

$Latent Heat$

$\\ \bold{Q} = heat \hspace{4} (J) \\ \bold{L} = average \hspace{4} coefficient \hspace{4} of \hspace{4} volume \\ \indent \hspace{6} expansion \hspace{4} (K^{-1}) \\ \bold{m} = mass \hspace{4} produced \hspace{4} through \hspace{4} phase \\ \indent \hspace{10} phase \hspace{4} change \hspace{4} (kg)$

Pressure - Volume Work

$Pressure - Volume Work$

$\\ \bold{W} = work \hspace{4} done \hspace{4} by \hspace{4} the \hspace{4} system \hspace{4} (J) \\ \bold{V_f} = final \hspace{4} volume \hspace{4} (m^3) \\ \bold{V_i} = initial \hspace{4} volume \hspace{4} (m^3) \\ \bold{P} = pressure \hspace{4} (Pa)$

First Law of Thermodynamics

$First Law of Thermodynamics$

$\\ \bold{\Delta E} = change \hspace{4} in \hspace{4} internal \hspace{4} energy \hspace{4} (J)\\ \bold{Q} = heat \hspace{4} transfer \hspace{4} in \hspace{4} to /out \hspace{4} of \\ \indent \hspace{6} the \hspace{4} system \hspace{4} (J) \\ \bold{W} = work \hspace{4} done \hspace{4} by/on \hspace{4} the \hspace{4} system \hspace{4} (J)$

Isobaric Work

$Isobaric Work$

$\\ \bold{W} = work \hspace{4} done \hspace{4} by \hspace{4} the \hspace{4} system \hspace{4} (J)\\ \bold{P} = pressure \hspace{4} (Pa) \\ \bold{\Delta V} = change \hspace{4} in \hspace{4} the \hspace{4} volume \hspace{4} of \\ \indent \hspace{21} the \hspace{4} system \hspace{4} (m^3)$

Isovolumetric Work

$Isovolumetric Work$

$\\ \bold{E} = change \hspace{4} in \hspace{4} internal \hspace{4} energy \hspace{4} (J) \\ \bold{Q} = heat \hspace{4} transfer \hspace{4} in \hspace{4} to/out \hspace{4} of \\ \indent \hspace{9} the \hspace{4} system \hspace{4} (J) \\$

Isothermal Work

$Isothermal Work$

$\\ \bold{W} = work \hspace{4} done \hspace{4} by \hspace{4} the \hspace{4} system \hspace{4} (J) \\ \bold{n} = number \hspace{4} of \hspace{4} moles \hspace{4} of \hspace{4} gas \hspace{4} (mol) \\ \bold{R} = gas \hspace{4} constant \hspace{4} (8.314 \hspace{2} J \hspace{2} K^{-1} \hspace{2} mol^{-1}) \\ \bold{T} = temperature \hspace{4} (K) \\ \bold{V_f} = final \hspace{4} volume \hspace{4} (m^3) \\ \bold{V_i} = initial \hspace{4} volume \hspace{4} (m^3)$

Fourier's Law of Conduction

$Fourier's Law of Conduction$

$\\ \bold{P} = energy \hspace{4} transfer \hspace{4} rate \hspace{4} due \\ \indent \hspace{8} to \hspace{4} conduction \hspace{4} (W) \\ \bold{k} = thermal \hspace{4} conductivity \hspace{4} (W \hspace{2} m^{-1} \hspace{2} K^{-1}) \\ \bold{A} = conduction \hspace{4} area \hspace{4} (m^2) \\ \bold{T} = temperature \hspace{4} (K) \\ \bold{x} = direction \hspace{4} of \hspace{4} heat \hspace{4} transfer \hspace{4} (m) \\$

Stefan-Boltzmann Law of Thermal Radiation

$Stefan - Boltzmann Law of Thermal Radiation$

$\\ \bold{P} = energy \hspace{4} transfer \hspace{4} rate \hspace{4} due \\ \indent \hspace{8} to \hspace{4} radiation \hspace{4} (W) \\ \bold{\sigma} = Stefan - Boltzmann \hspace{4} constant \\ \indent \hspace{4} (5.670 \times 10^8 \hspace{4} W \hspace{2} m^{-2} \hspace{2} K^{-4}) \\ \bold{A} = surface \hspace{4} area \hspace{4} of \hspace{4} object \hspace{4} (m^2) \\ \bold{\varepsilon} = emissivity \\ \bold{T} = temperature \hspace{4} (K) \\$

Pressure - Kinetic Energy Relationship

$Pressure - Kinetic Energy Relationship$

$\\ \bold{P} = pressure \hspace{4} (Pa) \\ \bold{N} = number \hspace{4} of \hspace{4} molecules \\ \bold{m} = mass \hspace{4} of \hspace{4} a \hspace{4} molecules \hspace{4} (kg)\\ \bar{{\hspace{2}v}} = average \hspace{4} velocity \hspace{4} of \hspace{4} the \\ \indent \hspace{4} molecules \hspace{4} (m \hspace{2} s^{-1}) \\ \bold{V} = volume \hspace{4} of \hspace{4} box \hspace{4} containing \\ \indent \hspace{10} the \hspace{4} gas \hspace{4} (m^3)$

Kinetic Energy

$Kinetic Energy$

$\\ \bold{K} = kinetic \hspace{4} energy \hspace{4} (J) \\ \bold{m} = mass \hspace{4} (kg) \\ \bold{v} = velocity \hspace{4} (m \hspace{2} s^{-1}) \\ \bold{k} = Boltzmann \hspace{4} constant \\ \indent \hspace{5} (1.38 \hspace{2} \times 10^{-23} \hspace{2} m^2 \hspace{2} kg \hspace{2} s^{-2} \hspace{2} K^{-1}) \\ \bold{T} = temperature \hspace{2} (K)$

Internal Energy of a Monoatomic Gas

$Internal Energy of a Monoatomic Gas$

$\\ \bold{\Delta E_{int}} = change \hspace{4} in \hspace{4} internal \hspace{4} energy \hspace{4} (J) \\ \bold{N} = number \hspace{4} of \hspace{4} atoms \\ \bold{k} = Boltzmann \hspace{4} constant \\ \indent \hspace{8} (1.38 \times 10^{-23} \hspace{2} m^2 \hspace{2} kg \hspace{2} s^{-2} \hspace{2} K^{-1})\\ \bold{T} = temperature \hspace{4} (K)\\ \bold{n} = number \hspace{4} of \hspace{4} moles \hspace{4} (mol) \\ \bold{R} = gas \hspace{4} constant \hspace{4} (8.314 \hspace{2} J \hspace{2} K^{-1} \hspace{4} mol^{-1})$

Molar Specific Heat at Constant Volume

$Molar Specific Heat at Constant Volume$

$\\ \bold{\Delta E_{int}} = change \hspace{4} in \hspace{4} internal \hspace{4} energy \hspace{4} (J) \\ \bold{n} = number \hspace{4} of \hspace{4} moles \hspace{4} (mol) \\ \bold{C_V} = molar \hspace{4} specific \hspace{4} heat \hspace{4} at \hspace{4} constant \\ \indent \hspace{15} volume \hspace{4} (J \hspace{4} mol^{-1} \hspace{2} K^{-1}) \\ \bold{\Delta T} = change \hspace{4} in \hspace{4} temperature \hspace{4} (K)\\$

Specific Heat for Ideal Monoatomic Gases

$Heat Capacities for Ideal Monoatomic Gases$

$\\ \bold{C_V} = specific \hspace{4} heat \hspace{4} for \hspace{4} ideal \\ \indent \hspace{15} monoatomic \hspace{4} gases \hspace{4} at \hspace{4} constant \\ \indent \hspace{15} volume \hspace{4} (J \hspace{4} mol^{-1} \hspace{2} K^{-1}) \\ \bold{C_P} = specific \hspace{4} heat \hspace{4} for \hspace{4} ideal \\ \indent \hspace{15} monoatomic \hspace{4} gases \hspace{4} at \hspace{4} constant \\ \indent \hspace{15} pressure \hspace{4} (J \hspace{4} mol^{-1} \hspace{2} K^{-1}) \\ \bold{R} = gas \hspace{4} constant \hspace{4} (8.314 \hspace{2} J \hspace{2} K^{-1} \hspace{4} mol^{-1})$

Relationship Between Specific Heats and Heat Capacities

$Relationship Between Specific Heats and Heat Capacities$

$\\ \bold{c_P} = specific \hspace{4} heat \hspace{4} under \\ \indent \hspace{10} constant \hspace{4} pressure \hspace{4} (J \hspace{2} K^{-1} \hspace{2} kg^{-1}) \\ \bold{C_P} = heat \hspace{4} capacity \hspace{4} under \\ \indent \hspace{10} constant \hspace{4} pressure \hspace{4} (J \hspace{2} K^{-1}) \\ \bold{c_V} = specific \hspace{4} heat \hspace{4} under \\ \indent \hspace{10} constant \hspace{4} volume \hspace{4} (J \hspace{2} K^{-1} \hspace{2} kg^{-1}) \\ \bold{C_V} = heat \hspace{4} capacity \hspace{4} under \\ \indent \hspace{10} constant \hspace{4} volume \hspace{4} (J \hspace{2} K^{-1}) \\ \bold{m} = mass \hspace{4} (kg)$

Heat Capacity Ratio for a Monoatomic Gas

$Heat Capacity Ratio for a Monoatomic Gas$

$\\ \bold{\gamma} = heat \hspace{4} capacity \hspace{4} ratio \\ \bold{c_P} = specific \hspace{4} heat \hspace{4} under \\ \indent \hspace{10} constant \hspace{4} pressure \hspace{4} (J \hspace{2} K^{-1} \hspace{2} kg^{-1}) \\ \bold{C_P} = heat \hspace{4} capacity \hspace{4} under \\ \indent \hspace{10} constant \hspace{4} pressure \hspace{4} (J \hspace{2} K^{-1}) \\ \bold{c_V} = specific \hspace{4} heat \hspace{4} under \\ \indent \hspace{10} constant \hspace{4} volume \hspace{4} (J \hspace{2} K^{-1} \hspace{2} kg^{-1}) \\ \bold{C_V} = heat \hspace{4} capacity \hspace{4} under \\ \indent \hspace{10} constant \hspace{4} volume \hspace{4} (J \hspace{2} K^{-1})$

Adiabatic Expansion / Compression of an Ideal Gas

$Adiabatic Expansion / Compression of an Ideal Gas$

$\\ \bold{P} = pressure \hspace{4} (Pa) \\ \bold{V} = volume \hspace{4} (m^3) \\ \bold{\gamma} = heat \hspace{4} capacity \hspace{4} ratio$

Boltzmann Distribution Law

$Boltzmann Distribution Law$

$\\ \bold{n_V} = number \hspace{4} density \hspace{4} (m^{-3}) \\ \bold{n_0} = number \hspace{4} of \hspace{4} molecules \hspace{4} with \\ \indent \hspace{12} energy \hspace{4} near \hspace{4} E \hspace{4} (m^{-3}) \\ \bold{E} = energy \hspace{4} (J) \\ \bold{k} = Boltzmann \hspace{4} constant \\ \indent \hspace{4} (1.38 \times 10^{-23} \hspace{2} m^2 \hspace{2} kg \hspace{2} s^{-2} \hspace{2} K^{-1}) \\ \bold{T} = temperature \hspace{4} (K)$

Maxwell - Boltzmann Speed Distribution Function

$Maxwell - Boltzmann Speed Distribution Function$

$\\ \bold{N_V} = distribution \hspace{4} of \hspace{4} speeds \hspace{4} (s\hspace{2}m^{-1}) \\ \bold{N} = number \hspace{4} of \hspace{4} molecules \\ \bold{m} = mass \hspace{4} (kg) \\ \bold{k} = Boltzmann \hspace{4} constant \\ \indent \hspace{4} (1.38 \times 10^{-23} \hspace{2} m^2 \hspace{2} kg \hspace{2} s^{-2} \hspace{2} K^{-1}) \\ \bold{T} = temperature \hspace{4} (K) \\ \bold{v} = speed \hspace{4} (m \hspace{2} s^{-1})$

Root - Mean - Square Speed

$Root - Mean - Square Speed$

$\\ \bold{V_{rms}} = root-mean-square \\ \indent \hspace{24} speed \hspace{4} (m \hspace{2} s^{-1}) \\ \bold{m} = mass \hspace{4} (kg) \\ \bold{k} = Boltzmann \hspace{4} constant \\ \indent \hspace{4} (1.38 \times 10^{-23} \hspace{2} m^2 \hspace{2} kg \hspace{2} s^{-2} \hspace{2} K^{-1}) \\ \bold{T} = temperature \hspace{4} (K) \\$

Average Speed

$Average Speed$

$\\ \bold{V_{avg}} = average \hspace{4} speed \hspace{4} (m \hspace{2} s^{-1}) \\ \bold{m} = mass \hspace{4} (kg) \\ \bold{k} = Boltzmann \hspace{4} constant \\ \indent \hspace{4} (1.38 \times 10^{-23} \hspace{2} m^2 \hspace{2} kg \hspace{2} s^{-2} \hspace{2} K^{-1}) \\ \bold{T} = temperature \hspace{4} (K) \\$

Most Probable Speed

$Most Probable Speed$

$\\ \bold{V_{mp}} = most \hspace{4} probable \\ \indent \hspace{24} speed \hspace{4} (m \hspace{2} s^{-1}) \\ \bold{m} = mass \hspace{4} (kg) \\ \bold{k} = Boltzmann \hspace{4} constant \\ \indent \hspace{4} (1.38 \times 10^{-23} \hspace{2} m^2 \hspace{2} kg \hspace{2} s^{-2} \hspace{2} K^{-1}) \\ \bold{T} = temperature \hspace{4} (K) \\$

Net Work Done by the Heat Engine

$Net Work Done by a Heat Engine$

$\\ \bold{W_{eng}} = net \hspace{4} work \hspace{4} done \hspace{4} by \hspace{4} the \\ \indent \hspace{28} heat \hspace{4} engine \hspace{4} (J) \\ \bold{Q_h} = energy \hspace{4} entering \hspace{4} the \\ \indent \hspace{14} engine \hspace{4} (J)\\ \bold{Q_c} = energy \hspace{4} leaving \hspace{4} the \\ \indent \hspace{14} engine \hspace{4} (J)\\$

Thermal Efficiency of a Heat Engine

$Thermal Efficiency of a Heat Engine$

$\\ \bold{e} = thermal \hspace{4} efficiency \hspace{4} of \hspace{4} a \\ \indent \hspace{4} heat \hspace{4} engine \hspace{4} (J) \\ \bold{W_{eng}} = net \hspace{4} work \hspace{4} done \hspace{4} by \hspace{4} the \\ \indent \hspace{28} heat \hspace{4} engine \hspace{4} (J) \\ \bold{Q_h} = energy \hspace{4} entering \hspace{4} the \\ \indent \hspace{14} engine \hspace{4} (J)\\ \bold{Q_c} = energy \hspace{4} leaving \hspace{4} the \\ \indent \hspace{14} engine \hspace{4} (J)\\$

Thermal Efficiency of a Heat Engine (Carnot Cycle)

$Thermal Efficiency of a Heat Engine (Carnot Cycle)$

$\\ \bold{e} = thermal \hspace{4} efficiency \hspace{4} of \hspace{4} a \\ \indent \hspace{4} heat \hspace{4} engine \hspace{4} operating \hspace{4} \\ \indent \hspace{4} in \hspace{4} the \hspace{4} Carnot \hspace{4} cycle \hspace{4} (J) \\ \bold{T_h} = temperature \hspace{4} of \hspace{4} the \hspace{4} hot \\ \indent \hspace{14} reservoir \hspace{4} (K)\\ \bold{T_c} = temperature \hspace{4} of \hspace{4} the \hspace{4} cold \\ \indent \hspace{14} reservoir \hspace{4} (K)\\$

Entropy - Microstate Relationship

$Entropy - Microstate Relationship$

$\\ \bold{S} = entropy \hspace{4} of \hspace{4} the \hspace{4} system \hspace{4} (J \hspace{2} K^{-1}) \\ \bold{k} = Boltzmann \hspace{4} constant \\ \indent \hspace{6} (1.381 \times 10^{-23} \hspace{2} m^2 \hspace{2} kg \hspace{2} s^{-2} \hspace{2} K^{-1}) \\ \bold{\Omega} = number \hspace{4} of \hspace{4} microstates$

Change in Entropy

$Change in the Entropy$

$\\ \bold{S} = entropy \hspace{4} (J \hspace{2} K^{-1}) \\ \bold{Q} = energy \hspace{4} transfer \hspace{4} in \hspace{4} a \hspace{4} \\ \indent \hspace{9} reversible \hspace{4} process \hspace{4} (J)\\ \bold{T} = temperature \hspace{4} (K)\\$

Change in Entropy in a Finite Process

$Change in the Entropy$

$\\ \bold{\Delta S} = change \hspace{4} in \hspace{4} entropy \hspace{4} (J \hspace{2} K^{-1}) \\ \bold{Q} = energy \hspace{4} transfer \hspace{4} in \hspace{4} a \hspace{4} \\ \indent \hspace{9} reversible \hspace{4} process \hspace{4} (J)\\ \bold{T} = temperature \hspace{4} (K)\\$

Return to AP Physics C

AP Physics C: Thermodynamics

AP Physics C:
Thermodynamics