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“K” Chemistry (part 1 of 3) Chapter 13: Reaction Rates and Kinetics
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Reaction Rates The rate of a chemical reaction is a measure of how fast the reaction occurs A slow reaction will have a small fraction of molecules reacting and forming products A fast reaction will have a large fraction of molecules reaction and forming products
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As the reactants react and form the products, the concentrations of each change as a function of time
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Rate Calculations For a balanced chemical reaction: aA + bB cC + dD
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Practice Consider the following balanced chemical equation: H 2 O 2(aq) + 3 I - (aq) + 2 H + (aq) I 3 - (aq) + 2 H 2 O (l) In the first 10.0 seconds of the reaction, the concentration of I - dropped from 1.000 M to 0.868 M. (a)Calculate the average rate of this reaction in this time interval (b)Predict the rate of change in the concentration of H + (Δ[H + ] / Δ t) during this time interval
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Practice Using the above reaction, predict the rate of change in concentration of hydrogen peroxide and the I 3 -1 during the same time interval
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Rate Laws The rate of a reaction depends on the concentration of one or more of the reactants For example (a simple decomposition reaction): A Products As long as the reverse reaction is negligibly slow (or non existent), we can write a relationship (a rate law) Rate = k [A] n
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Rate Laws Rate = k [A] n k is the proportionality constant called the rate constant n is a number called the reaction order – IT IS NOT NUMBER OF MOLES OR THE STOICHIOMETRY COEFFICIENT!!! – It MUST be determined experimentally!!
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Reaction Order, n If n = 0, the reaction is zero order and the rate is independent of the concentration of A – By mathematical definition, [A] 0 = 1 so the rate law (Rate = k [A] 0 ) is equal to k regardless of the concentration of A If n = 1, the reaction is first order and the rate is directly proportional to the concentration of A If n = 2, the reaction is second order and the rate is proportional to the square of the concentration of A
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Zero-Order Reaction Rate = k [A] 0 = k For a zero order reaction, the concentration of the reactant decreases linearly with time The rate is constant because it does not slow down as the [A] decreases
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First-Order Reaction Rate = k [A] 1 For a first order, the rate is directly proportional to the concentration of the reactant Consequently, the rate slows as the concentration of the reactant decreases
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Second-Order Reaction Rate = k [A] 2 For a second order reaction, the rate of the reaction is proportional to the square of the concentration of the reactant Consequently, the rate is even more sensitive to the reaction concentration
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Quick Tip The “order of the reactant” refers to only the reactant of focus A Products Rate = k [A] n This reaction is n th order with respect to “reactant A” A “reaction order” is the sum of all the exponents
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Determining the Order of the Reaction The order of the reaction can only be determined by experiment Uses a method called the method of initial rates – The rate for a short period of time at the beginning of the reaction is measured using different initial reactant concentrations to determine the effect of [A] has on the rate
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Method of Initial Rates Notice for this data: – When the concentration of A doubles, the rate is directly proportional… the rxn is therefore first order with respect to “reactant A” [A] (M)Initial Rate (M/s) 0.100.015 0.200.030 0.400.060
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The Value of the Rate Constant, k The rate constant, k, can be calculated using this experimentally determined data after the determination of the orders (the exponents) Rate = k [A]1 k = rate/[A] = (0.015 M*s -1 ) / (0.10M) = 0.15s -1 NOTICE THAT: the rate constant for a first-order reaction is s -1
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Data for Zero-Order Notice for this data: – The initial rate is independent for the reactant concentration – the rate is the same at all measured initial concentrations [A] (M)Initial Rate (M/s) 0.100.015 0.200.015 0.400.015
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Data for Second-Order Notice for this data: – The initial rate quadruples for a doubling of a reactant concentration. The relationship between concentration and rate is quadratic. [A] (M)Initial Rate (M/s) 0.100.015 0.200.060 0.400.240
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KEY THINGS!! The rate constants for zero- and second-order reactions have different units than first-order NOTICE THAT: – the rate constant for a zero-order reaction is M*s -1 – the rate constant for a first-order reaction is s -1 – the rate constant for a second-order reaction is M -1 *s -1
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Reaction Order for Multiple Reactants (not a simple decomp.) aA + bB cC + dD Again, as long as the reverse is negligibly slow (or non-existent), the rate law can be defined as: Rate = k [A] m [B] n m is the reaction order with respect to A n is the reaction order WRT B The overall order is the sum of the exponents (m+n)
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Example The reaction between hydrogen gas and iodine has been experimentally determined to be first order WRT both reactants… and thus second order OVERALL H 2(g) + I 2(g) 2HI (g) Rate =k[H 2 ] 1 [I 2 ] 1 The exponents ARE NOT THE COEFFICIENTS!!
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Example The reaction between hydrogen and nitrogen monoxide has been experimentally determined to be first order WRT hydrogen and second order WRT to nitrogen monoxide 2H 2(g) + 2NO (g) N 2(g) + 2H 2 O (g) Rate = k[H 2 ] 1 [NO] 2 **Notice the exponents are the ‘experimentally determined’ orders… NOT THE COEFFICIENTS!!
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Practice Calculating Orders Consider the following reaction between NO 2 and CO: NO 2(g) + CO (g) NO (g) + CO 2(g) The initial rate of the reaction was measured at several different concentrations if the reactants with the following results: Calculate the rate law for the reaction AND the rate constant (k) [NO 2 ] (M)[CO] (M)Initial Rate (M/s) 0.10 0.0021 0.200.100.0082 0.20 0.0083 0.400.100.033
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Look for anything held constant!! – If you compare the rates while one reactant is held constant than you can assume the reaction rate is CAUSED by the reactant that is changing!! The [NO 2 ] doubled while the rate quadrupled – Implies this rxn is second order WRT to NO 2 The [CO] (while the [NO2] is constant) doubles while the rate is unchanged… implying zero order [NO 2 ] (M)[CO] (M)Initial Rate (M/s) 0.10 0.0021 0.200.100.0082 0.20 0.0083 0.400.100.033
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Rate = k[NO 2 ] 2 [CO] 0 = k[NO 2 ] 2 Now, calculate the k – plug in any two corresponding data points = 0.21 M -1 *s -1 **Notice the UNITS!! [NO 2 ] (M)[CO] (M)Initial Rate (M/s) 0.10 0.0021 0.200.100.0082 0.20 0.0083 0.400.100.033
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Practice #2 Consider the following reaction: CHCl 3(g) + Cl 2(g) CCl 4(g) + HCl (g) Calculate the rate law for the reaction AND the rate constant (k) [CHCl 3 ] (M)[Cl 2 ] (M)Initial Rate (M/s) 0.010 0.0035 0.0200.0100.0069 0.020 0.0127 0.040 0.027
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Half Life (t 1/2 ) Read through pages 584-587 and work out the half life problems – In a nutshell, the half life is the time it takes for half of a sample to disappear (break down / decompose)
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RATE LAW SUMMARY
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Effects of Temperature – Effects of Pressure (for gases) – Activation Energy – Catalysis – – Enzymes – Collision Theory – Rate Determining Step –
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End of Chapter 13 WORK THROUGH THE PRACTICE PROBLEMS!!!
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