Rate Equations

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Created by
Ashling Asirifi

Cards (49)

  • Rate Equation
    The rate equation relates mathematically the rate of reaction to the concentration of the reactants
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  • Rate Equation
    1. aA + bB → products
    2. r = k[A]m[B]n
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  • r
    Symbol for rate
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  • Unit of r
    mol dm-3 s-1
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  • [A]
    Concentration of A (unit mol dm-3)
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  • k
    Rate constant
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  • m, n
    Reaction orders
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  • Orders are usually integers 0, 1, 2
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  • 0 order
    Reaction is zero order with respect to that reactant
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  • 1st order
    Rate of reaction is directly proportional to the concentration of A
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  • 2nd order

    Rate of reaction is proportional to the concentration of A squared
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  • The total order for a reaction is worked out by adding all the individual orders together (m+n)
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  • Zero order

    The concentration of A has no effect on the rate of reaction
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  • First order

    r = k[A]1
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  • Second order
    r = k[A]2
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  • Rate constant (k)

    • The units of k depend on the overall order of reaction
    • The value of k is independent of concentration and time. It is constant at a fixed temperature
    • The value of k refers to a specific temperature and it increases if we increase temperature
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  • Unit of k for 1st order
    1. 1
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  • Unit of k for 2nd order
    mol-1dm3s-1
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  • Unit of k for 3rd order
    mol-2dm6s-1
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  • Example 1 (first order overall)
    1. Rate = k[A][B]0
    2. m = 1 and n = 0
    3. Reaction is first order in A and zero order in B
    4. Overall order = 1 + 0 = 1
    5. Usually written: Rate = k[A]
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  • Calculating units of k
    1. Rearrange rate equation to give k as subject
    2. Insert units and cancel
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  • Example 2: Write rate equation for reaction between A and B where A is 1st order and B is 2nd order
    1. r = k[A][B]2
    2. Overall order is 3
    3. Calculate the unit of k
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  • Continuous Monitoring
    Following one experiment over time recording the change in concentration
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  • The gradient represents the rate of reaction. The reaction is fastest at the start where the gradient is steepest.
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  • Measurement of the change in volume of a gas
    1. Mg + 2HCl → MgCl2 + H2
    2. Using a gas syringe is a common way of following this
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  • The initial rate is the rate at the start of the reaction, where it is fastest. It can be calculated from the gradient of a continuous monitoring conc vs time graph at time = zero.
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  • Large excess of reactants
    If the concentration of one of the reactant is kept in a large excess then that reactant will appear not to affect rate and will be pseudo-zero order
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  • Comparing continuous rate curves
    1. Need to calculate/ compare initial moles of reactants to distinguish between different finishing volumes
    2. Different volumes of the same initial concentrations will have the same initial rate (if other conditions are the same) but will end at different amounts
    3. The higher the concentration/ temperature/ surface area the faster the rate (steeper the gradient)
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  • Initial rate method
    • The initial rate can be calculated from taking the gradient of a continuous monitoring conc vs time graph at time = zero
    • Initial rate can also be calculated from clock reactions where the time taken to reach a fixed concentration is measured
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  • A Common Clock Reaction
    1. H2O2(aq) + 2H+(aq) + 2I–(aq) → I2(aq) + 2H2O(l)
    2. 2S2O32–(aq) + I2(aq) → 2I–(aq) + S4O62–(aq)
    3. When the I2 produced has reacted with all of the limited amount of thiosulfate ions present, excess I2 remains in solution. Reaction with the starch then suddenly forms a dark blue-black colour.
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  • Example 3: Deduce the rate equation for the following reaction, A+ B+ 2C → D + 2E, using the initial rate data in the table

    1. Compare between experiments to determine the order with respect to each reactant
    2. The overall rate equation is r = k [A] [B]2
    3. The reaction is 3rd order overall and the unit of the rate constant = mol-2dm6s-1
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  • Working out order graphically

    1. Log rate = log k + n log [Y]
    2. A graph of log rate vs log [Y] will yield a straight line where the gradient is equal to the order n
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  • Working out orders when two reactant concentrations are changed simultaneously
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  • Log rate
    log k + n log [Y]
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  • Graph of log rate vs log [Y]
    • Yields a straight line
    • Gradient is equal to the order n
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  • Rate equation
    Y = c + m x
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  • High concentrations with quick times will have the biggest percentage errors
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  • Working out orders from experimental initial rate data
    1. Do a series of experiments where the initial concentrations of reactants are changed (one at a time)
    2. Measure the initial rate each time
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  • log (rate)
    • y intercept = log K
    • Gradient = n = change in y / change in x
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  • Working out orders when two reactant concentrations are changed simultaneously
    1. Compare between two experiments where only one reactant has its initial concentration changed
    2. If both reactants are changed, the effect of both individual changes on concentration are multiplied together to give on overall change on rate
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