Three common mechanisms for bimolecular quenching

Slides:



Advertisements
Similar presentations
Chemical Kinetics Reaction rate - the change in concentration of reactant or product per unit time.
Advertisements

Atmospheric chemistry
Atkins & de Paula: Atkins’ Physical Chemistry 9e
Atkins & de Paula: Atkins’ Physical Chemistry 9e
CHEMICAL KINETICS CHAPTER 17, Kinetics Fall 2009, CHEM
22.6 Elementary reactions Elementary reactions: reactions which involve only a small number of molecules or ions. A typical example: H + Br 2 → HBr + Br.
AP Chapter 14.  Chemical kinetics is the area of chemistry that involves the rates or speeds of chemical reactions.  The more collisions there are between.
Copyright © by Holt, Rinehart and Winston. All rights reserved. Ch. 17 Reaction Kinetics Understanding chemical reactions that occur at different rates.
Three common mechanisms for bimolecular quenching
Chemical Kinetics. Chemical kinetics - speed or rate at which a reaction occurs How are rates of reactions affected by Reactant concentration? Temperature?
Fundamentals of air Pollution – Atmospheric Photochemistry - Part A Yaacov Mamane Visiting Scientist NCR, Rome Dec May 2007 CNR, Monterotondo, Italy.
Chapter 24. Molecular Reaction Dynamics Purpose: Calculation of rate constants for simple elementary reactions. For reactions to take place: 1. Reactant.
22.5 The temperature dependence of reaction rates Arrhenius equation: A is the pre-exponential factor; E a is the activation energy. The two quantities,
1 MAE 5310: COMBUSTION FUNDAMENTALS Introduction to Chemical Kinetics September 24, 2012 Mechanical and Aerospace Engineering Department Florida Institute.
Chemistry 232 Chemical Kinetics. Chemical kinetics - speed or rate at which a reaction occurs How are rates of reactions affected by Reactant concentration?
The Kinetic Theory of Matter states that matter is composed of a large number a small particles—individual atoms or molecules—that are in constant motion.
Chemical Kinetics Unit 11. Chemical Kinetics Chemical equations do not give us information on how fast a reaction goes from reactants to products. KINETICS:
Rates of Reactions Why study rates?
C h a p t e r 12 Chemical Kinetics. Reaction Rates01 Reaction Rate: The change in the concentration of a reactant or a product with time (M/s). Reactant.
Molecular Reaction Dynamics. Collision Theory of Kinetics With few exceptions, the reaction rate increases with increasing temperature temperature If.
Scanning excitation and emission spectra I Wavelength (nm) )Scan excitation with emission set at 380 nm -λ ex,max = 280 nm 2) Scan emission.
23.7 Kinetics of photochemical reactions
Dr. Mihelcic Honors Chemistry1 Chemical Kinetics Rates and Mechanisms of Chemical Reactions.
METO 637 Lesson 4. Electronically Excited Species Electronically excited species can be formed as the result of optical pumping, photo- fragmentation,
Mechanisms of enzyme inhibition Competitive inhibition: the inhibitor (I) binds only to the active site. EI ↔ E + I Non-competitive inhibition: binds to.
Förster Resonance Energy Transfer (FRET)
Kinetics.
22.6 Elementary reactions Elementary reactions: reactions which involves only a small number of molecules or ions. A typical example: H + Br 2 → HBr +
Chapter 5 Rates of Chemical Reaction. 5-1 Rates and Mechanisms of Chemical Reactions 5-2 Theories of Reaction Rate 5-3 Reaction Rates and Concentrations.
Chemical Kinetics. A brief note on Collision Theory All matter is made up of particles: atoms, molecules and ions. Kinetics is all about how chemicals.
Dr. Paul Charlesworth Michigan Technological University Dr. Paul Charlesworth Michigan Technological University C h a p t e rC h a p t e r C h a p t e.
Objectives Explain the concept of reaction mechanism. Use the collision theory to interpret chemical reactions. Define activated complex. Relate activation.
Stoichiometry is the study of quantitative (i. e
Rate Expression and reaction mechanism
Study of Reaction Rates Grab your text book.
Some reactions occur is several sequential steps.
Chemical Kinetics Chapter 13.
Chemical Kinetics Unit 10 – Chapter 12.
UNIT 3: Energy Changes and Rates of Reaction
Midterm 2 (53 students wrote the exam)
Chapter 14 Honors Chemistry
Three common mechanisms for bimolecular quenching
SECTION 1. THE REACTION PROCESS
Rate Theories of elementary reaction
Chemical Kinetics Chapter 13.
SANTOSH CHEMISTRY DEPT
Chemical Kinetics First and Second Laws of thermodynamics are used to predict the final equilibrium state of the products after the reaction is complete.
26.11 Kinetics of photochemical reactions
The steric effect Steric factor, P, Reactive cross-section, σ*,
Part 3: Reaction Mechanisms
CHEMICAL KINETICS Chpt 12
Kinetics and Rate Law.
BY JHERUDDEN PGT (CHEMISTRY) KV SECL,NOWROZABAD
Chapter 27. Molecular Reaction Dynamics
KINETICS Chapter 16.
Chemical Kinetics.
Chemical Kinetics Courtesy: Nearing Zero.net.
Quenching The presence of a quencher, Q, opens an additional channel for deactivation of S* S* + Q → S + Q vQ = kQ[Q][S*] Now the steady-state.
Modified by Jed Macosko
CHEM 3310 Chemical Kinetics Collision Theory & Transition State Theory.
Chapter 16 Preview Objectives Thermochemistry Heat and Temperature
大气圈地球化学及其环境效益.
Kinetics Chapter 14.
Chemical Kinetics Chapter 13.
Chemical Kinetics Lesson 2
23.7 Kinetics of photochemical reactions
Lecture 15.
Chemical Kinetics Chapter 13.
Section 1 The Reaction Process
Lecture 21.
Presentation transcript:

Three common mechanisms for bimolecular quenching 1. Collisional deactivation: S* + Q → S + Q is particularly efficient when Q is a heavy species such as iodide ion. 2. Resonance energy transfer: S* + Q → S + Q* 3. Electron transfer: S* + Q → S+ + Q- or S* + Q → S- + Q+

Energy Transfer Processes (Forster theory,1952) Energy transfer is more efficient when 1. The energy donor and acceptor are separated by a short distance, in the nanometer scale 2. Photons emitted by the excited state of the donor can be absorbed directly by the acceptor The efficiency of energy transfer, ET, equals Where R is the distance between the donor and the acceptor. R0 is a parameter that is characteristic of each donor-acceptor pair. Fluorescence resonance energy transfer (FRET)

Electron transfer reactions (Marcus theory) The distance between the donor and acceptor, with electron transfer becoming more efficient as the distance between donor and acceptor decrease. The reaction Gibbs energy, ∆rG, with electron transfer becoming more efficient as the reaction becomes more exergonic. The reorganization energy, the energy cost incurred by molecular rearrangements of donor, acceptor, and medium during electron transfer. The electron transfer rate is predicted to increase as this reorganization energy is matched closely by the reaction Gibbs energy.

23.8 Complex photochemical processes The overall quantum yield of a photochemical reaction. (can be larger than 1) Rate laws of complex photochemical reactions. Photosensitization (no direct absorption).

Quantum yield of a complex photochemical reaction Overall quantum yield: the number of reactant molecules consumed per photon absorbed: For example: HI + hv → H. + I. HI + H. → H2 + I. I. + I. + M → I2 + M* Here the overall quantum yield is two, because the absorption of one photon destroys two reactant molecules HI. Therefore, in a chain reaction the overall quantum yield can be very large.

Rate laws of complex photochemical reactions. See example: 23.21 (8th edition)

Photosensitization Example: hydrogen gas containing trace amount of mercury. The synthesis of formaldehyde H. + CO -> HCO. HCO. + H2 -> HCHO + H. HCO. + HCO. -> HCHO + CO Photodynamic therapy

Example: When a sample of 4-heptane was irradiated for 100s with 313 nm radiation with a power output of 50W under conditions of total absorption, it was found that 2.8 mmol C2H4 was formed. What is the quantum yield for the formation of ethylene? Solution: First calculate the number of photons generated in the interval 100s. Then divide the amount of ethylene molecules formed by the amount of photons absorbed. N(photons) = P∆t/(hc/λ) Ф = n(C2H4)*NA/N = 0.21

Chapter 24. Molecular Reaction Dynamics Purpose: Calculation of rate constants for simple elementary reactions. For reactions to take place: 1. Reactant molecules must meet. 2. Must hold a minimum energy. Gas phase reactions: Collision theory. Solution phase reactions: Diffusion controlled. Activation controlled.

24.1 Collision theory Consider a bimolecular elementary reaction A + B → P v = k2[A][B] The rate of v is proportional to the rate of collision, and therefore to the mean speed of the molecules, Because a collision will be successful only if the kinetic energy exceeds a minimum value. It thus suggests that the rate constant should also be proportional to a Boltzmann factor of the form, . Consider the steric factor, P, Therefore, k2 is proportional to the product of steric requirement x encounter rate x minimum energy requirement

Collision rate in gases Collision density, ZAB, is the number of (A, B) collisions in a region of the sample in an interval of time divided by the volume of the region and the duration of the interval. where σ = d2 d = ½(dA + dB) and u is the reduced mass when A and B are the same, one gets The collision density for nitrogen at room temperature and pressure, with d = 280 pm, Z = 5 x 1034 m-3s-1.

The energy requirement For a collision with a specific relative speed of approach vrel reorganize the rate constant as Assuming that the reactive collision cross-section is zero below εa

The steric effect Steric factor, P, Reactive cross-section, σ*, Harpoon mechanism: Electron transfer preceded the atom extraction. It extends the cross-section for the reactive encounter. K and Br2 reaction

Example 24.1 Estimate the steric factor for the reaction H2 + C2H4 -> C2H6 at 628K given that the pre-exponential factor is 1.24 x 106 L mol-1 s-1. Solution: Calculate the reduced mass of the colliding pair From Table 24.1 σ(H2) = 0.27 nm2 and σ(C2H4) = 0.64 nm2, given a mean collision cross-section of σ = 0.46 nm2. P = 1.24 x 106 L mol-1 s-1/7.37 x 1011 L mol-1s-1 = 1.7 x 10-6

Solution: The above reaction involves electron flip Example 24.2: Estimate the steric factor for the reaction: K + Br2 → KBr + Br Solution: The above reaction involves electron flip K + Br2 → K+ + Br2- Three types of energies are involved in the above process: (1) Ionization energy of K, I (2) Electron affinity of Br2, Eea (3) Coulombic interaction energy: Electron flip occurs when the sum of the above three energies changes sign from positive to negative

24.2 Diffusion-controlled reactions Cage effect: The lingering of one molecule near another on account of the hindering presence of solvent molecules. Classes of reaction Suppose that the rate of formation of an encounter pair AB is first-order in each of the reactants A and B: A + B →AB v = kd[A][B] The encounter pair, AB, has the following two fates: AB → A + B v = kd’[AB] AB → P v = ka[AB] The net rate of change of [AB]: = kd[A][B] - kd’[AB] - ka[AB]

Invoking steady-state approximation to [AB] The net rate of the production: When kd’<< ka k2 = kd (This is diffusion-controlled limit) When kd’>> ka (This is activation-controlled reaction)

Reaction and Diffusion where R* is the distance between the reactant molecules and D is the sum of the diffusion coefficients of the two reactant species (DA + DB). where η is the viscosity of the medium. RA and RB are the hydrodynamic radius of A and B. If we assume RA = RB = 1/2R*

24.3 The material balance equation (a) The formulation of the equation the net rate of change due to chemical reactions the over rate of change the above equation is called the material balance equation.

(b) Solutions of the equation