Chemistry: Thermochemistry Flashcards

Question

Standard Heat of Reaction

Answer 1

deltaHrxn. It's the hypothetical enthalpy change that would occur if the reaction were carried out under standard conditions; i.e., when reactants int heir standard states are converted to products in their standard states at 298K. It can be expressed as deltaHrxn = (sum of deltaHf products) - (sum of deltaHf reactants)

Answer 2

States that enthalpies of reactions are additive. Specifically, Hess's law states that when the reactants are transformed into products, the net change in enthalpy is the same irrespective if the reaction takes place in a series of steps or in a single step. When thermochemical equations (chemical equations for which energy changes are known) are added to give the net equation for a reaction, the corresponding heats of reaction are also added to give the net heat of reaction. Because enthalpy is a state function, the enthalpy of a reaction doesn't depend on the path taken, only on the initial and final states.

Answer 3

Heats of reaction are related to changes in energy associated with the breakdown and formation of chemical bonds. Bond energy, or bond dissociation energy, is an average of the energy required to break a particular type of bond in one mole of gaseous molecules. It's tabulated as the positive value of the energy absorbed as the bonds are broken. Bond energies can be used to estimate enthalpies of reactions. The enthalpy change of reaction is deltaHrxn = (deltaH of bonds broken) + (deltaH of bonds formed) = total energy input - total energy released Note: Since energy is released when bonds are formed, the deltaH of bonds formed will be negative.

Answer 4

One more type of standard enthalpy change that's often used is the standard heat of combustion. deltaHcomb. As stated earlier, a requirement for relatively easy measurement of deltaH is that the reaction be fast and spontaneous; combustion generally fits this description.

Answer 5

Measure of disorder, or randomness, of a system. The units of entropy are energy/temperature, commonly J/K or cal/K. The greater the order in a system, the lower the entropy; the greater the disorder or randomness, higher the entropy. At any given temperature, a solid will have lower entropy than a gas, because individual molecules int he gaseous state are moving randomly, while individual molecules in a solid are constrained in place. Entropy is a state function, so a change in entropy depends only on the initial and final states: deltaS = Sfinal - Sinitial

Answer 6

A change in entropy is also given by: deltaS = qrev/T where qrev is the heat added to the system undergoing a reversible process (a process that proceeds with infinitesimal changes in the system's conditions) and T is the absolute temperature.

Answer 7

A standard entropy change for a reaction is calculated using the standard entropies of reactants and products: deltaSrxn = (sum of deltaSproducts) - (sum of deltaSreactants)

Answer 8

The second law of thermodynamics states that all spontaneous processes proceed such that the entropy of the system plus its surroundings increases: deltaSuniverse = deltaSsystem + deltaSsurroundings > 0 A system reaches its max entropy at equilibrium, a state in which no observable change takes place as time goes on. A system will spontaneously tend toward an equilibrium state if left alone.

Answer 9

Combines the two factors that affect the spotaneity of a reaction, changes in enthalpy and changes in entropy. The change in the free energy of a system, deltaG, represents the max amount of energy released by a process, occurring at constant temperature and pressure, that's available to perform useful work. deltaG = deltaH - TdeltaS where T is the absolute temperature and TdeltaS represents the total amount of heat absorbed by a system when its entropy increases reversibly.

Answer 10

In the equilibrium state, free energy is at a minimum. A process can occur spontaneously if the Gibbs function decreases (i.e., deltaG > 0). - If deltaG is negative, the reaction is spontaneous. - If deltaG is positive, the reaction is not spontaneous. - If deltaG is zero, the system is in a state of quilibrium. Thus, if deltaG = 0, then deltaH = TdeltaS The rate of a reaction depends on the activation energy, not the deltaG.

Answer 11

Defined as the deltaG of a process occurring at 25 degrees Celsius and 1 atm pressure and for which the concentrations of any solutions involved are 1 M. The standard free energy of formation of a compound, deltaGf, is the free-energy change that occurs when one mole of a compound in its standard state is formed from its elements in their standard states under standard conditions. The standard free energy of formation of any element in its most stable form (and, therefore, its standard state) is zero. The standard free energy of a reaction, deltaGrxn, is the free energy change that occurs when that reaction is carried out under standard state conditions; i.e., when the reactants in their standard states are converted to the products in their standard states, at standard condition of T and P. For example, conversion of C(diamond) to C(graphite) is spontaneous under standard conditions. However, its rate is so slow that the rxn is never observed. deltaGrxn = (sum of deltaGf of products) - (sum of deltaGf of reactants)

Answer 12

deltaGrxn can also be derived from the quilibrium constant for the equation: deltaGdegree = -RTlnKeq where Keq is the equilibrium constant, R is the gas constant, and T is the temperature in K. Once a reaction commences, however, the standard state conditions no longer hold. Keq must be repalced by another parameter, the reaction quotient (Q). For the reaction, aA + bB cC + dD: {Q=[C]^c[D]^d}/{[A]^a[B]^b} Likewise, deltaG must be used in place of deltaGdegree. deltaG = deltaGdegree + RTlnQ where R is the gas constant and T is the temperature in K.

Chemistry: Thermochemistry Flashcards

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