What is thermodynamics?

What is thermodynamics? Chapter 1

Muscular Energy Kinetic Energy Chapter 1

C H O H 2 O H O H H H O H H H O H O H Glucose Chemical Energy Muscular Energy Chapter 1

Solar Energy Chemical Energy Chapter 1

Big Bang H2 Nuclear Fusion Sunlight Plant Food Energy Fun Chapter 1

What is thermodynamics? • The word thermo-dynamic was first used by Kelvin in 1849. • Today we define thermodynamics as the science that deals with the interconversion of heat and work and all its applications. Chapter 1

Highlights in thermodynamics • Black (1760-1766), calorimetry • Mayer and Joule (1842-1852), interconversion of heat and work • Kelvin (1848-1849), absolute temperature scale (K) • Clausius (1850), second law • Kelvin (1851), second law, dissipation of energy • Clausius (1854-1865), concept of entropy • Gibbs (1873), chemical thermodynamics • Gibbs (1876-1878), chemical potential, phase rule • Helmholtz (1882), equilibrium, free and bound energy • Van’t Hoff (1884-1887), equilibrium constant, solutions • Nernst (1906), heat theorem (third law) • Simon (1927), improved version of third law Chapter 1

Important Concepts • System: any designated volume of space. • Surroundings: everything else in the universe. Chapter 1

Important Concepts • State: a collection of all measurable macroscopic properties (variables) of a system. • State function: any property that depends only on the state variables. All state variables are also state functions. Is work a state function? Chapter 1

Important Concepts • Intensive property: non-additive properties of a system. E.g. pressure, temperature • Extensive property: additive properties of a system. E.g. volume, energy A state variable or function is also an intensive property. Chapter 1

Equations of State • A relationship between several state variables of a system. • E.g. the ideal gas law PV = nRT Remember this equation. Chapter 1

Important Concepts • Constraint: variables that are not allowed to change during a process. • Equilibrium: A system is at equilibrium if its state does not change with time. When a system is in equilibrium with its surroundings, it has unconstrained variables which are neither changing nor causing any changes in the surroundings. Chapter 1

Temperature is An intensive property A state variable A state function All of the above An intensive property A state variable A state function Temperature, Heat and Thermometers Heat is • An extensive property • An interaction between two systems • A form of energy Chapter 1

Absolute Temperature Scale • According to the ideal gas law PV = nRT If we graph PV against T, we have That makes me the absolute zero. PV Chapter 1 T

All thermodynamic equations are written in terms of the absolute temperature scale T K = T ºC + 273.15 Chapter 1

A process is A way to cause a change in a system Defined by the beginning and end states of the system A reversible process is One during which the system is constantly in equilibrium with its surroundings. Processes Real processes are never reversible. Chapter 1

Isothermal Constant temperature during entire process Closed Nothing goes into or out of the system. Processes adiabatic • No heat flow during entire process Isolated • No interaction with its environment in any way I only reject heat. I reject everything! Chapter 1

Calculations in SI Units n R T P = V (moles) (8.314 JK-1 mol-1) (Kelvin) (m3) (Pascals) Check out Appendix D! Stick with SI units. Make fewer errors. Chapter 1

Sign Convention All quantities are expressed relative to the system, not to the surroundings. Disagree! + - Chapter 1

Specific vs Total Quantities • V: non-specific volume • V: mole-specific volume, or molar specific volume, volume based on unit mole • V: mass-specific volume, volume based on unit mass ~ Chapter 1

Example 1.3 The molar specific heat capacity (Cp) of lead is 26.4 JK-1 mol-1. What is the heat capacity of 1 gram lead? 26.4 JK-1 mol-1 Cp = ________________= 0.127 JK-1 g-1 207.2 g/mol ~ Know how to convert between specific and total quantities. Chapter 1

What is thermodynamics?