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Introduction to thermochemistry

Introduction to thermochemistry. Heat, work, energy and the First Law. Learning objectives. Define energy and identify types of energy Compare and contrast heat and work Describe internal energy and how it changes during a process Describe basic properties of state functions

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Introduction to thermochemistry

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  1. Introduction to thermochemistry Heat, work, energy and the First Law

  2. Learning objectives • Define energy and identify types of energy • Compare and contrast heat and work • Describe internal energy and how it changes during a process • Describe basic properties of state functions • Apply first law of thermodynamics to determine heat flow and work • Define enthalpy

  3. Behind it all • Why do things happen in chemistry? • Substances spontaneously move towards a position of greater stability – in energy terms • A high energy state is unstable with respect to a state of lower energy • A simple (but incomplete) analogy is a ball rolling downhill

  4. Energy • Is capacity to perform work • Mechanical work is application of force over distance • Heat is energy transferred by virtue of temperature gradient – associated with molecular motion • Joule demonstrated experimentally that heat and work are interchangeable forms of energy

  5. Energy: forms • Kinetic energy is the energy of motion • Potential energy is energy stored – by position, within a spring, within a chemical bond, within the particles of a nucleus

  6. Energy: units • From the definition of kinetic energy (1/2mv2), we get the units of energy: kg m2/s2 • S.I. unit for energy is the joule (J) = 1Nm • Another common unit is the calorie (cal): the energy required to raise the temperature of 1 g of water by 1ºC 1 cal = 4.184 J • Note the food calorie (Cal) = 1 000 cal

  7. Interchange and conservation • Energy in its many forms can be changed from one to another • A stationary ball on a hill has potential energy (P.E.) by virtue of position but no kinetic energy (K.E.). As it rolls down, it gains K.E. at the expense of P.E.

  8. Energy conservation • There is no gain or loss: Energy cannot be created or destroyed; it can only be changed from one form to another • Chemical processes involve conversion of chemical potential energy into other forms and vice versa • Energy never goes away, but in some forms it is more useful than others • Efficient energy use means maximizing the useful part and minimizing the useless part

  9. Some like it hot • Thermal energy is the kinetic energy of molecular motion • Temperature measures the magnitude of the thermal energy • Heat is the transfer of thermal energy from a hotter to a cooler body • Temperature gradient provides the “pressure” for heat to flow • Chemical energy is the potential energy stored in chemical bonds

  10. System and surroundings • Any process can be divided into the SYSTEM contained within the SURROUNDINGS • When energy changes are measured in a chemical reaction, the system is the reaction mixture and the surroundings are the flask, the room, and the rest of the universe.

  11. Internal energy • Internal energy is the sum of all of the types of energy (kinetic and potential) of the system. It is the capacity of the system to do work • Typically we don’t know the absolute value of U for the system • (Internal energy usually has symbol U. Other sources use E) • We can measure the change to the internal energy ΔU = Ufinal - Uinitial

  12. Work and internal energy • Work done on system increases its internal energy • Work done by system decreases its internal energy ΔU = w

  13. Workin’ for a livin’ • Mechanical work is force applied over a distance W = F x d • In chemical process release of gas allows work to be done by system

  14. Work done at constant pressure • Gas generated in reaction pushes against the piston with force: P x A • At constant P, volume increases by ΔV and work done by system is: w = -PΔV (ΔV = A x d) • Work done by system is –ve in expansion (ΔV > 0) • ΔU < 0 (ΔV > 0, -PΔV < 0) • Work done by system is +ve in contraction (ΔV < 0) • ΔU > 0 (ΔV < 0, -PΔV > 0)

  15. Expansion work • Work done by gas expanding: w = -PexΔV • In expansion the ΔV > 0; w < 0 ΔU < 0 • In contraction, ΔV < 0; w > 0 ΔU > 0

  16. Heat and internal energy • Heat is transfer of energy by virtue of temperature gradient ΔU = q • If system is cooler than surroundings q > 0 • If system is hotter than surroundings q < 0

  17. Deposits and withdrawals • Process is always viewed from perspective of system • Energy leaving system has negative sign • (decreases internal energy – lowers the chemical bank balance) • Energy entering system has positive sign • (increases internal energy – increases chemical bank balance) • Useful process is one where change is negative • Energy is in the form of heat or work • ΔU = q + w

  18. First Law of Thermodynamics Total internal energy of isolated system is constant • Energy change is difference between final and initial states (ΔU = Ufinal – Uinitial) • Energy that flows from system to surroundings has negative sign (Ufinal < Uinitial,) • Energy that flows into system from surroundings has positive sign (Ufinal > Uinitial.)

  19. Functions of state • State Function A property that depends only on present state of the system and is independent of pathway to that state • Internal energy is a state function, as are pressure, volume and temperature

  20. Significance of state functions • Change in state function between two states is independent of pathway • Given two states of a system: • ΔU is always the same • q and w depend on type of change

  21. Heat and work • Any chemical process may have associated with it heat and work terms • The total internal energy change will be the sum of the contributions from each ΔU = q + w = q - P ΔV q = ΔU + P ΔV • In a sealed system ΔV = 0, so q = ΔU

  22. Cracked pots and enthalpy • Most reactions are conducted in open vessels where P is constant and ΔV ≠ 0 • The heat change at constant pressure is qP = ΔU + P ΔV • Enthalpy (H) is defined as: H = U + PV

  23. Heats of reaction and enthalpy • Absolute enthalpy of system is not known • Enthalpy change is measured • Enthalpy change is known as heat of reaction ΔH = qP = ΔU + P ΔV • If reaction is exothermic and involves expansion: • ΔU < 0, ΔV > 0 ΔH less negative than ΔU • Enthalpy change is portion of internal energy available as heat after work is done • If no work done, all the internal energy change is enthalpy

  24. Comparing ΔH and ΔU • In reactions involving volume change at constant P, ΔH and ΔU are different. How big is it? • Consider reaction: • 1 additional mole of gas is produced ΔU = - 2045 kJ, ΔH = - 2043 kJ PΔV = + 2kJ

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