chapter 10

Created by

Amber Rafiq

Cards (29)

a rate of reaction measures how fast a reactant is used up or how fast a product is formed
rate of reaction is calculated by doing the change in concentration of reactant or product divided by the given time
the rate of reaction is fastest at the start of the reaction, as each reactant is at its highest concentration
the rate of reaction slows down as the reaction proceeds, because the reactants are being used up and their concentrations decrease
once one of the reactants has been completely used up, the concentrations stops changing and the rate of reaction is zero
factors that affect rate of reaction
concentration( or pressure if reactants are gas)
temperature
catalyst
surface area of solid reactants
collision theory states that two reacting particles must collide for a reaction to occur
an effective collsion has:
correct orientation
sufficient energy
when concentration increases, rate of reaction increases as the number of particles in a given volume is increased, so they are closer, so they collide more frequently, so their will be more effective collisions in a given time
increasing pressure of a gas increases concentration, so there will be more in a given volume, which are closer, so collide more often, more successful collisions means a faster rate of reaction
the progress of a chemical reaction can be measured by:
monitoring removal of reactant
following the formation of products
a catalyst increases rate of reaction by providing an alternative reaction pathway of lower activation energy. at the end, the catalyst is regenerated
a homogeneous catalyst is the same state as the reactant. it forms an intermmediate, which breaks down to form products
a heterogeneous catalyst is a different state to the reactants. it absorbs reactant molecules onto the surface, reacts, then desorbs the product molecules
the haber process uses an iron catalyst. hydrogenation of alkenes uses a nickel catalyst
catalysts can reduce temp needed, which lowers energy and electricity costs, increasing profitability
industries want to focus on sustainability by doing processes that have high atom economies and fewer pollutants
the Boltzmann distribution shows the spread of molecular energies in gases.
in the Boltzmann distribution:
the curve starts at the origin to show that no molecules have zero energy
the area under the curve is the total number of molecules
there is no maximum energy for a molecule, so the x axis would go on forever
as temperature increases on the Boltzmann distribution, the curve become shorter and shifts the right, and the number of particles that can react is larger
on the Boltzmann distribution, a catalyst shifts the activation energy to the left, increasing the number of particles that can react
in dynamic equilibrium:
the rate of the forward reaction is equal to the rate of the backward reaction
the concentrations of the reactants and products don't change
le chateliers principle states that when a system in equilibrium is subjected to an external change, the system readjusts itself to minimise the effect of that change
when the temperature increases, the endothermic reaction is favoured, and when the temperature decreases, the exothermic reaction is favoured
when pressure is increases the side with least gaseous molecules will be favoured, but when pressure decreases the side with most gaseous moles is favoured
a catalyst does not affect the position of equilibrium
the equilibrium law:
$K^c=$ $[C]^c .[D]^d / [A]^a . [B]^b$
in the equilibrium law:
square brackets mean the concentration
the small letters are the number of balancing moles
a kc value of:
1= equilibrium
1+=products favoured
-1= reactants favoured