Chemical Kinetics Reaction Rate Cheat Sheet, Cheat Sheet of Chemical Kinetics

Download Chemical Kinetics Reaction Rate Cheat Sheet and more Cheat Sheet Chemical Kinetics in PDF only on Docsity! Chapter 13 Kinetics Student notes page 1 of 8 CHAPTER 13. CHEMICAL KINETICS Kinetics - Study of factors that affect how fast a reaction occurs and the step-by-step processes involved in chemical reactions. Factors that Affect Reaction Rate A. Concentration of reactants - higher reactant concentrations increase the rate of reaction. B. Catalyst – substance that accelerates the reaction rate without being transformed. C. Temperature - higher temperatures usually increase the rate of reaction. D. Surface area of solid - smaller particles have more surface area so the rate increases. 13.1. THE RATE OF A REACTION Rate of reaction: The change in the amount of a reactant or product per unit time. (Analogy: speed of an automobile = ∆Distance/∆time.) Average Rate = time ionconcentrat ∆ ∆ [ ] = concentration E.g. For a reaction A → B Average Rate for B = = ; Average Rate for A = = • The reaction rate is a measure of how fast a reaction occurs. • Rate can be expressed as the rate of formation of products or the rate of disappearance of reactants. • Reaction rate is always positive, so a (-) sign is used for reactant rate expressions. (Because the concentration of reactants decreases with time, ∆[Reactants] is a negative quantity.) • Reaction rate decreases with time ⇒ slope of curve decreases as reaction progresses. Experimental Determination of Rate We can find the rate of reaction by measuring the concentration of a reactant or product during the course of the reaction. Concentration can be obtained by different methods including titration, spectroscopy, and by taking manometer pressure readings. Spectrometer Measurements E.g. Br2 + HCO2H → 2Br - + 2H+ + CO2 A colored species, Br2, is consumed during this reaction, so we can use a spectrophotometer to measure the absorbance of light over a series of time intervals. (The absorbance is proportional to the concentration of Br2.) The concentration of Br2 vs. time can then be plotted as shown in Figure 13.5. Example. Calculate the average rate from t = 50.0 s to 100.0 s instantaneous rate: Rate at a specific point in time. Analogy: the speed a car is traveling when a photo radar camera snaps the picture. conc. time B A Chapter 13 Kinetics Student notes page 2 of 8 To calculate instantaneous rate - draw a line tangent to the curve at a given instant in time & find the slope of the line. Example. Instantaneous Rate at t = 200.0 s: *Due to estimating the values used in determining the slope of the line, the value that you obtain for the instantaneous rate may differ from the instantaneous rates given in your text book. Gas Phase Reactions If one of the substances in the reaction mixture is a gas, manometer readings can be taken to monitor the pressure of the gas. e.g. 2H2O2(aq) → O2(g) + 2H2O(l) The rate of oxygen evolution can be measured with a manometer. The pressure of oxygen can then be converted to concentration by using the ideal gas law: PV = nRT Concentration can be expressed as: M L moles V n == By substitution: P = MRT or RT PM = Reaction Rates & Stoichiometry Consider the reaction: 2N2O5 → 4NO2 + O2 • For this reaction, the rate of disappearance of N2O5 is twice the rate of formation of O2. • To make the rates equal, divide rates by their stoichiometric coefficients: Rate = - t2 1 ∆ ∆ ][ 52ON = 4 1 t 2 ∆ ∆ ][NO = t 2 ∆ ∆ ][O Example. For the reaction, 3H2 + N2 → 2NH3, write the rate expressions in terms of the disappearance of the reactants and the appearance of the products. Example. For the reaction, 2N2O5 → 4NO2 + O2, if the rate of decomposition of N2O5 is 4.2x10-7 mol/(L⋅s), what is the rate of appearance of (a) NO2; (b) O2? 13.2. THE RATE LAW Rate law: gives relationship of the reaction rate to the rate constant and the concentrations of the reactants. E.g. 2N2O5 → 4NO2 + O2 Rate = k[N2O5] k = Rate Constant: k is a numerical constant for a reaction at a given temperature. • k is not affected by [Reactants], but reaction rate is affected by [Reactants]. Chapter 13 Kinetics Student notes page 5 of 8 Characteristics of zero, first and second order reactions Order Rate Law Integrated Law Linear graph slope Half-life 0 Rate = k [A]t = -kt + [A]0 [A] vs. t -k t1/2 = 2k [A]0 1 Rate = k[A] ln       0 t [A] [A] = - kt ln [A] vs. t -k t1/2 = k 0.693 2 Rate = k[A]2 t[A] 1 = kt + 0[A] 1 t[A] 1 vs. t +k t1/2 = 0k[A] 1 Graphical Method of Determining Rate Law 1) Make 3 plots: [A] vs time; ln [A] vs. time; and [A] 1 vs. time. 2) The most linear plot gives the correct order for A; the other 2 graphs should be curves. 13.4 ACTIVATION ENERGY AND TEMPERATURE DEPENDENCE OF RATE CONSTANTS Collision Theory: Molecules must collide with each other in order to react! Collision frequency affects the reaction rate: • An increase in [Reactant] results in more collisions, so the rate of reaction is faster. • ↑T causes molecules to move faster and collide more frequently, increasing the rate. Transition State Theory However, only a small fraction of colliding molecules will react because: 1) the molecules must possess enough Kinetic Energy to A. overcome e-cloud - e-cloud repulsions B. transfer translational KE to vibrational energy to weaken/break reactant bonds Molecules at a given Temperature possess a KE distribution: Number of molecules KE Ea Ea, Activation Energy - Energy barrier that molecules have to surmount in order to react. Energy is needed to break reactant bonds (endothermic process). analogies: putting a golf ball over a hill or getting started on an unpleasant task • Only a small fraction of molecules have high enough KE to initiate a reaction. • Ea is different for each reaction – for reactions with low Ea, the reaction rate is faster and k is larger because more molecules can overcome Ea. • At higher temperatures, a larger fraction of molecules have enough KE to surmount Ea. (This is the primary reason that the reaction rate increases rapidly as temperature rises.) 2) molecules must be properly oriented to have an effective collision. Figure 13.17: K + CH3I → KI + CH3 • K must collide with I in order for the reaction to occur. low T high T Chapter 13 Kinetics Student notes page 6 of 8 Activated Complex (transition state) – a highly unstable species formed by the collision of the reactant molecules; arrangement of atoms at the top of the energy barrier. e.g. O=N + Cl-Cl → O=N---Cl---Cl → O=N-Cl + Cl Reactants Activated Complex Products Potential energy diagram for endothermic reaction: Reaction progress ∆H = Heat of reaction; this is ∆H(products) – ∆H(reactants). The Ea shown above is the activation energy for the forward reaction, Ea(forward). This is the difference in energy between the activated complex and the reactants. There is also an activation energy associated with the reverse process, Ea(reverse). This is the difference in energy between the activated complex and the products. Potential energy diagram for exothermic reaction: transition state Reaction progress Arrhenius Equation The Arrhenius equation gives the relationship between the rate constant and the temperature: k = Ae-Ea/RT (e = ln-1 or inv ln) R = gas constant = 8.314 J/K-mol, T = temperature in K e-Ea/RT = fraction of molecules that have enough KE to react A = frequency factor (relates to # of collisions that are properly oriented) By taking the natural log of both sides and rearranging, we obtain: ln k = -       T 1 R Ea + ln A • plot of ln k vs 1/T yields a straight line ⇒ • slope= R Ea− ; y intercept = ln A Non-graphical method: If you have 2 sets of conditions, solve for k1, k2, T1, T2 or Ea using: ln       2 1 k k = R Ea       − 12 11 TT ∆H Ea E ∆H Ea E O=N + Cl -Cl O=N-- Cl -- Cl O=N- Cl + Cl ln k 1/T Chapter 13 Kinetics Student notes page 7 of 8 13.5 REACTION MECHANISMS Many chemical reactions occur by a sequence of 2 or more steps – the specific sequence of steps is referred to as the reaction mechanism. Each individual event in the overall reaction is called an elementary step. Molecularity: number of molecules that react in an elementary step Unimolecular: 1 molecule A → products Bimolecular: 2 molecules 2A → products or A + B → products Termolecular (uncommon): 3A → products or 2A + B → P or A + B + C → P Example. The 2 step mechanism for the overall reaction Br2 + 2NO → 2BrNO is: Step 1: Br2 + NO → Br2NO (Bimolecular step) Step 2: Br2NO + NO → 2BrNO (Bimolecular step) Intermediates are short lived species that are formed during the reaction, then are subsequently consumed. Intermediates do not appear in the overall balanced equation. e.g. Br2NO for the example above ⇒ For an elementary step, the rate law can be written using the stoichiometric coefficients of the reactants (molecularity = order). E.g. Step 1 in the reaction above: Rate = Rate determining step: the slowest step in the reaction is the rate determining step; this step limits how fast products can form. Analogy: freeway during rush hour ⇒ The rate law for the overall reaction is determined by the rate of this step. Mechanisms with an Initial Slow Step Example. The mechanism for the overall reaction 2NO2 + F2 → 2NO2F is proposed to be: Step 1: NO2 + F2 → NO2F + F (slow) Step 2: F + NO2 → NO2F (fast) What is the Rate Law for this reaction? Rate = ⇒ The reactants for the slow step (step 1) give us the rate law for the overall reaction. Mechanisms with an Initial Fast Equilibrium Step Many chemical reactions involve mechanisms with equilibrium steps: Example. The mechanism for the reaction Br2 + 2NO → 2BrNO occurs via two steps: Step 1: Br2 + NO ⇄ Br2NO (fast equilibrium) Step 2: Br2NO + NO → 2BrNO (slow) What is the Rate Law predicted by this mechanism? ⇒ From the slow step: Rate = ⇒ However, it is not possible to accurately measure the concentration of an intermediate so an intermediate cannot be part of an experimental rate law. ⇒ Since most of Br2NO decomposes during the equilibrium reaction established in step 1, we can set up an equilibrium expression based on the rates of the forward and reverse reactions: