CHM1046 Exam 2 Dr.Dillon
Reactions can be spontaneous but
this does not mean they occur fast
Enthalpy
total energy of a system (difference between products and reactants)
Examples of catalysts
Nickel Iron Platinum
Maxwell-Boltzmann distribution
Shows the spread of energies that molecules of gas or liquid have at a particular temperature
intermediates
Those reactants and products that appear only in an elementary reaction but not in the overall reaction
half life formula for zero order
[A]0/2k
homogeneous catalyst
a catalyst that is in the same phase as all the reactants and products in a reaction system -usually dispersed in liquid -less expensive -can be designed to function selectively
catalytic converter
a device that reduces carbon monoxide emissions from vehicles.
reaction rates
a measure of how quickly reactants turn into products
reaction mechanism
a series of elementary reactions that take place during the course of a complex reaction
bimolecular elementary reaction
a+b->products
most important type of homogeneous catalysts in a liquid
acid and base catalyts
the elementary steps must
add up to the overall equation, physically reasonable, correlate with the rate law
catalyts are not
altered
average rates
an overall rate measured over a period or time interval
enzyme catalysis
biological catalysts
X+Y=Z Rate of reaction=?
change in [Z]/change in time
rate of reaction equals
change in concentration/change in time
Reaction occur the fastest when molecules are
colliding quickly
rate of reaction depends on
collision frequency and collision energy
termolecular reaction
elementary step with 3 molecules
cataysts do not affect
enthalpy
spontanueous proccesses
physical or chemical change that occurs with no outside intervention however some energy may be supplied to get the process in action (activation energy)
unimolecular elementary reaction
product
units of k for zero order
mol/L*s
poor orientation=
no reaction
Increasing temperature increases
rate constant
zero order reaction
rate is independent of the concentration of the reactant.
1st order reaction
rate=k[A]
instantaneous rate
rates measured at any point during the reaction
initial rates
rates measured at the beginning of the reaction, which is dependent on the initial concentrations of the reactants
integrated rate law
relationship between the concentrations of the reactants and time
applicatios of kinetics
shelf life, drug metabolism, food preservation, radiation
differential rate law
shows how the rate of reaction depends on the concentration
catalyst
substance that speeds up the rate of a chemical reaction
collisions need
sufficient energy/velocity
integrated rate law tells us
the concentration as a function of time
determining step
the slowest step in a complex reaction
Ina reaction, as the pressure increases
the space in which the particles are moving becomes smaller
Kinetics
the study of reaction rates
chemical kinetics
the study of reaction rates, how reaction rates change under varying conditions and by which mechanism the reaction proceeds.
overall reaction order
the sum of all the exponents in a rate law expression
activation energy
Energy needed to get a reaction started
collision theory
For a reaction to occur, the particles must collide, they must collide with the appropriate orientation, and they must collide with sufficient energy.
frequency factor
-"A" in Arrhenius equation -also known as "attempt frequency" -a measure of how often molecules in a certain reaction collide -units of s ^-1
half life formula for second order
1/k[A]0
units of k for first order
1/s
heterogeneous catalyst
A catalyst that is in a different phase from that of the reactant substances.
Enzymes
Catalysts for chemical reactions in living things -highly specific
units of k for second order
L/mol*sec
units for k third order
L^2/mol^2*s
higher order reactions
Reactions in which more than two species are involved, or one species reacts with stoichiometric coefficient >2
2nd-order reactions of Class I
Reactions in which the rate varies with concentration of a single species, but the stoichiometric coefficient is 2. The rate varies with the reciprocal of the concentration, so a plot of 1/(concentration) versus time is linear.
2nd-order reactions of Class II:
Reactions in which the rate varies with the concentration of two species, each of which has a stoichiometric coefficient of 1. A plot of ln(concentration .A/concentration B) versus time is linear.
enzyme-substrate complex
When an enzyme binds to its substrate, it forms:
half life formula for first order
ln(2)/k
rate laws are
how the rate depends on amounts of reactants
Factors that effect the rate of a reaction
increasing temperature, concentration of the reactants, surface area, catalysts, physical states, light, increased pressure
Arhenius equation
k = Ae^(-Ea/RT)
Arrhenius equation
k=Ae^(-Ea/RT); relationship between rates and temperatures
rate law
k[A]^n; works when temp is constant
half life
length of time required for half of the radioactive atoms in a sample to decay
Two-point form of Arrhenius equation
ln (k2/k1) = Ea/R (1/T1 - 1/T2)
