Systems

In thermodynamics we must define the part of the universe where the energy changes occur
System: part of the universe that we are studying
Surroundings: everything outside of the system
Open system: matter & energy exchange with surroundings
Closed system: exchanges energy as work and/or heat (but not matter)
Isolated system: neither matter nor energy exchanged

First Law of Thermodynamics

First law of thermodynamics: energy is conserved
Internal energy, U, of a system: the sum of ALL potential and kinetic energies of the components of the system
A precise, numerical value cannot be determined
We consider only the change in internal energy
- delta U = Ufinal – Uinitial
delta U = q + w

Depend only on the present state of the system and NOT on the PATH by which the system arrived at that state
The internal energy of the system is the same regardless of which PATH was used

“PV-work” is work involved in expansion or compression of gases
At constant pressure: w = -P(delta V)
If delta V is + → expansion of gas; system does work on surroundings and w is negative
If delta V is - → compression of gas; work is done on the system and w is positive
Like internal energy E, both P and V are state functions
We can combine these state functions to define “ENTHALPY”, H
- H = U + PV
At constant pressure: delta H = delta E + P(delta V)
- delta H = delta U + P(delta V) = (qpw) –w = qp
- delta H = qp
  - This equation is important because qp is easily measured
If delta H is positive, the reaction is endothermic
If delta H is negative, the reaction is exothermic
Reversing the direction of a reaction changes the sign of delta H
If the coefficients of a chemical reaction are multiplied by some factor, the enthalpy change must also be multiplied by that factor
- (delta H is an extensive property).
Enthalpy change depends on the physical states of reactants and products and these states must be specified.

The reaction is carried out in aqueous solution
System = reactants and products Surroundings includes the water
Heat released or absorbed by the reaction changes the temperature of the solution
delta H can be determined experimentally by measuring heat flow for a reaction at constant pressure

Heat capacity: the amount of heat required to raise the temperature of an object by one degree C or K
Specific heat: the heat capacity of one gram of a substance; Cs

Enthalpy of formation: the enthalpy change for the reaction in which one mole of a substance is made from its constituent elements in their elemental (most stable) forms.
Standard enthalpies of formation: measured under standard conditions

In thermodynamics we must define the part of the universe where the energy changes occur
System: part of the universe that we are studying
Surroundings: everything outside of the system
Open system: matter & energy exchange with surroundings
Closed system: exchanges energy as work and/or heat (but not matter)
Isolated system: neither matter nor energy exchanged

First law of thermodynamics: energy is conserved
Internal energy, U, of a system: the sum of ALL potential and kinetic energies of the components of the system
A precise, numerical value cannot be determined
We consider only the change in internal energy
- delta U = Ufinal – Uinitial
delta U = q + w

Depend only on the present state of the system and NOT on the PATH by which the system arrived at that state
The internal energy of the system is the same regardless of which PATH was used

“PV-work” is work involved in expansion or compression of gases
At constant pressure: w = -P(delta V)
If delta V is + → expansion of gas; system does work on surroundings and w is negative
If delta V is - → compression of gas; work is done on the system and w is positive
Like internal energy E, both P and V are state functions
We can combine these state functions to define “ENTHALPY”, H
- H = U + PV
At constant pressure: delta H = delta E + P(delta V)
- delta H = delta U + P(delta V) = (qpw) –w = qp
- delta H = qp
  - This equation is important because qp is easily measured
If delta H is positive, the reaction is endothermic
If delta H is negative, the reaction is exothermic
Reversing the direction of a reaction changes the sign of delta H
If the coefficients of a chemical reaction are multiplied by some factor, the enthalpy change must also be multiplied by that factor
- (delta H is an extensive property).
Enthalpy change depends on the physical states of reactants and products and these states must be specified.

The reaction is carried out in aqueous solution
System = reactants and products Surroundings includes the water
Heat released or absorbed by the reaction changes the temperature of the solution
delta H can be determined experimentally by measuring heat flow for a reaction at constant pressure

Heat capacity: the amount of heat required to raise the temperature of an object by one degree C or K
Specific heat: the heat capacity of one gram of a substance; Cs

Enthalpy of formation: the enthalpy change for the reaction in which one mole of a substance is made from its constituent elements in their elemental (most stable) forms.
Standard enthalpies of formation: measured under standard conditions