Study Notes
Study Notes
CHEM 1101
Study Notes 1901 Thermochemistry Work π€ = πΉ Γ π (πππππ Γ πππ π‘ππππ) Conversions 1πππ’ππ = 1πππ2 πβ2 1 πππππππ = 4.184 πππ’πππ First Law of Energy is never created nor destroyed, it is conserved. Thermodynamics I.e. Ξ΅E is constant. If system loses energy surroundings gain proportionate amount. βπ = ππππππ β πππππ‘πππ Summary of +ve q = heat gained -ve q = heat lost Energy Exchange +ve w = work done on system -ve w = work done by system +ve βπ = energy gain -ve βπ = energy loss State functions Absolute value of internal energy of system usually indeterminate. Internal energy is a state function. This means that it depends only on the state of the system not on the path at which the system arrived at that state. Q and W are not state functions i.e. Whether a battery shorts out or is discharged the change in energy is the same, but Q and w are different. Enthalpy Is equal to the internal energy of the system plus the product of pressure and volume ( H = U + PV). At constant pressure is equal to the amount of heat gained or lost. Enthalpy is an extensive property (i.e. it depends on the amount of reactants/products). Calorimetry The measurement of heat flow. This is measured by the magnitude of the temperature change resultant from heat flow. At a constant volume the βπ and not the βπ» is always measured Heat Capacity The heat capacity is the amount of energy required to raise the temperature of a substance by one and the Specific Kelvin / one degree (Celsius). The specific heat capacity is the amount of energy required to raise the Heat Capacity temperature of 1g of substance by 1K.
π=
π
πβπ
βπ π» is the enthalpy change for the reaction in which a compound is made from its constituent elements in their elemental forms. βπ π» Is the enthalpy of formation under standard conditions. Different states mean different enthalpies of formation. E.g. πΆ3 π»8 + 5π2 β 3πΆπ2 + 4π»2 π = πΆ3 π»8 β 3πΆ + 4π»2 = ββπ π» ππ πΆ3 π»8 = 3πΆ + 3π2 β 3πΆπ2 = 3(βπ π» ππ πΆπ2 ) = 4π»2 + 2π2 β 4π»2 π = 4(βπ π» ππ π»2 π)
Enthalpy of Formation
Spontaneous Processes Real Processes 2nd Law of Thermodynamics Boltzmannβs Equation
1
Total βπ π» = β πβπ π»πππππ’ππ‘π β β πβπ π»πππππ‘πππ‘π β΄ = [3(β393.5) + 4(β285.8)] β [(β10385) + 5(0)] = 2220ππ½ Can be changed by different temperatures and pressures. For example ice β melts spontaneously when T>0 All real processes are irreversible. Any irreversible process results in an overall increase in entropy, whereas a reversible process results in no change in entropy. Total entropy of the universe increases in any spontaneous reaction. Molecules are in constant motion. If we consider one mole of a particular gas then, at any instant, the particular set of positions and energyβs of the individual gas molecules is called a microstate of the thermodynamic system. A microstate is a single possible arrangement of the positions and kinetic energies of the gas molecules when the gas is in a specific thermodynamic state. π = ππππ (π = πππ‘ππππ¦ π = ππ. ππ ππππππ π‘ππ‘ππ π = 1.38 Γ 10β23 π½πΎ β ) Entropy is a measure of the number of microstates that are associated with a particular macroscopic state. Entropy increases for processes where gases are formed from either solids or liquids, liquids of solutions are formed from solids or the number of gas molecules increases during a chemical reaction. Entropies increase with mass and with the number of atoms in a molecules as well as vibrational degrees of freedom.
CHEM 1101
Study Notes 1901 Thermochemistry Work π€ = πΉ Γ π (πππππ Γ πππ π‘ππππ) Conversions 1πππ’ππ = 1πππ2 πβ2 1 πππππππ = 4.184 πππ’πππ First Law of Energy is never created nor destroyed, it is conserved. Thermodynamics I.e. Ξ΅E is constant. If system loses energy surroundings gain proportionate amount. βπ = ππππππ β πππππ‘πππ Summary of +ve q = heat gained -ve q = heat lost Energy Exchange +ve w = work done on system -ve w = work done by system +ve βπ = energy gain -ve βπ = energy loss State functions Absolute value of internal energy of system usually indeterminate. Internal energy is a state function. This means that it depends only on the state of the system not on the path at which the system arrived at that state. Q and W are not state functions i.e. Whether a battery shorts out or is discharged the change in energy is the same, but Q and w are different. Enthalpy Is equal to the internal energy of the system plus the product of pressure and volume ( H = U + PV). At constant pressure is equal to the amount of heat gained or lost. Enthalpy is an extensive property (i.e. it depends on the amount of reactants/products). Calorimetry The measurement of heat flow. This is measured by the magnitude of the temperature change resultant from heat flow. At a constant volume the βπ and not the βπ» is always measured Heat Capacity The heat capacity is the amount of energy required to raise the temperature of a substance by one and the Specific Kelvin / one degree (Celsius). The specific heat capacity is the amount of energy required to raise the Heat Capacity temperature of 1g of substance by 1K.
π=
π
πβπ
βπ π» is the enthalpy change for the reaction in which a compound is made from its constituent elements in their elemental forms. βπ π» Is the enthalpy of formation under standard conditions. Different states mean different enthalpies of formation. E.g. πΆ3 π»8 + 5π2 β 3πΆπ2 + 4π»2 π = πΆ3 π»8 β 3πΆ + 4π»2 = ββπ π» ππ πΆ3 π»8 = 3πΆ + 3π2 β 3πΆπ2 = 3(βπ π» ππ πΆπ2 ) = 4π»2 + 2π2 β 4π»2 π = 4(βπ π» ππ π»2 π)
Enthalpy of Formation
Spontaneous Processes Real Processes 2nd Law of Thermodynamics Boltzmannβs Equation
1
Total βπ π» = β πβπ π»πππππ’ππ‘π β β πβπ π»πππππ‘πππ‘π β΄ = [3(β393.5) + 4(β285.8)] β [(β10385) + 5(0)] = 2220ππ½ Can be changed by different temperatures and pressures. For example ice β melts spontaneously when T>0 All real processes are irreversible. Any irreversible process results in an overall increase in entropy, whereas a reversible process results in no change in entropy. Total entropy of the universe increases in any spontaneous reaction. Molecules are in constant motion. If we consider one mole of a particular gas then, at any instant, the particular set of positions and energyβs of the individual gas molecules is called a microstate of the thermodynamic system. A microstate is a single possible arrangement of the positions and kinetic energies of the gas molecules when the gas is in a specific thermodynamic state. π = ππππ (π = πππ‘ππππ¦ π = ππ. ππ ππππππ π‘ππ‘ππ π = 1.38 Γ 10β23 π½πΎ β ) Entropy is a measure of the number of microstates that are associated with a particular macroscopic state. Entropy increases for processes where gases are formed from either solids or liquids, liquids of solutions are formed from solids or the number of gas molecules increases during a chemical reaction. Entropies increase with mass and with the number of atoms in a molecules as well as vibrational degrees of freedom.
