Reaction Rate Chapter 16 What is reaction rate

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Reaction Rate Chapter 16

Reaction Rate Chapter 16

What is reaction rate The time taken for the disappearance of the reactant or

What is reaction rate The time taken for the disappearance of the reactant or the appearance of the product. Rate is a ratio as the amount of reactant disappeared divided by the time. Average rate: The change in the concentration divided by the total time elapsed. Rate = amount reacted or produced/ time interval units: g/s, mol/s, or %/s

 Instantaneous rate: rate measured between very short interval Initial rate: instantaneous rate at

Instantaneous rate: rate measured between very short interval Initial rate: instantaneous rate at the beginning of an experiment

Class Practice Page 592 Concept check

Class Practice Page 592 Concept check

 Rate depends on the concentration: In some reactions doubling the concentration doubles the

Rate depends on the concentration: In some reactions doubling the concentration doubles the rate of reaction. In some doubling the reaction increases the reaction four folds. This happens in the decomposition of HI to form H 2 and I 2.

Rate Laws An expression for the rate of a reaction as a function of

Rate Laws An expression for the rate of a reaction as a function of the concentration of one or more of the reactants. Rate=k [A]n This equation is the general rate law. The exponent n , is called the order with respect to substance A and must be determined from experimental data.

 Order of a chemical reaction can be said as the exponent on the

Order of a chemical reaction can be said as the exponent on the concentration for a specified reactant in a rate law expression.

Class Practice Determine the rate law equation for the following reaction , given the

Class Practice Determine the rate law equation for the following reaction , given the experimental data 3 A C Concentration of A Reaction rate 0. 2 M 1. 0 M/s 0. 4 M 4. 0 M/s

Home work Page 596 Practice problems

Home work Page 596 Practice problems

Rate laws for reactions with more than one reactant The rate law equations you

Rate laws for reactions with more than one reactant The rate law equations you have looked so far have been for reactions involving only one reactant. If more than one reactant is found to contribute to the rate of the reaction, then all contributing reactants must appear in the rate law. The rate law equation for this will be rate=k [A] n [B] m

 The value of n is the order with respect to reactant A. The

The value of n is the order with respect to reactant A. The value of m is the order with respect to reactant B. The overall reaction order will be the sum of n and m. From the above equation if you double the concentration of A and the rate doubles then the reaction is first order with respect to A. If you double the conc. of B (keeping the conc of A constant, and the rate quadruples the rate of the reaction is second order with respect to B.

 For the reaction A and B for this example the rate law would

For the reaction A and B for this example the rate law would be rate=k[A][B]2 Rate laws cannot be derived from a chemical equation. 2 N 2 O₅↔ 4 NO 2+O 2 Keq=[NO 2] 4 [O 2]/[N 2 O₅]2 rate=k[N 2 O₅]1

Rate determining step The slowest step in a mechanism, the step that determines the

Rate determining step The slowest step in a mechanism, the step that determines the overall rate of reaction is the rate determining step. Mechanism is a proposed sequence of steps that describes how reactants are changed into products. Each step in the mechanism is called as elementary step.

Home work Page 598 Critical thinking 2, 3, 5 Practice problems 7 and 8

Home work Page 598 Critical thinking 2, 3, 5 Practice problems 7 and 8 all

Factors that influence rate of reaction Temperature: An increase in temperature is accompanied by

Factors that influence rate of reaction Temperature: An increase in temperature is accompanied by an increase in the reaction rate. Temperature is a measure of the kinetic energy of a system, so higher temperature means higher average kinetic energy of molecules and more collisions per unit time. For most chemical reactions the rate at which the reaction proceeds will approximately double for each 10°C increase in temperature. Once the temperature reaches a certain point, some of the chemical species may be altered (e. g. , denaturing of proteins) and the chemical reaction will slow or stop.

 Concentration: A higher concentration of reactants leads to more effective collisions per unit

Concentration: A higher concentration of reactants leads to more effective collisions per unit time, which leads to an increasing reaction rate (except for zero order reactions). Similarly, a higher concentration of products tends to be associated with a lower reaction rate.

 Medium: The rate of a chemical reaction depends on the medium in which

Medium: The rate of a chemical reaction depends on the medium in which the reaction occurs. It sometimes could make a difference whether a medium is aqueous or organic; polar or nonpolar; or liquid, solid, or gaseous.

 Surface area: It is easier to dissolve sugar if it is crushed. Crushing

Surface area: It is easier to dissolve sugar if it is crushed. Crushing the sugar increases its surface tension. The larger surface area allows more sugar molecules to contact the solution.

 Catalyst: A catalyst is a substance that alters the rate of a chemical

Catalyst: A catalyst is a substance that alters the rate of a chemical reaction without being used up or permanently changed chemically. A catalyst works by changing the energy pathway for a chemical reaction. It provides an alternative route (mechanism) that lowers the Activation Energy meaning more particles now have the required energy needed to undergo a successful collision.

 What is activation energy? The least amount of energy needed to permit a

What is activation energy? The least amount of energy needed to permit a particular chemical reaction.

Types of catalyst There are 2 types of catalysts: Homogeneous catalysts are in the

Types of catalyst There are 2 types of catalysts: Homogeneous catalysts are in the same phase as the reactants. Heterogeneous catalyst: Heterogeneous catalysts are present in different phases from the reactants (for example, a solid catalyst in a liquid reaction mixture), whereas homogeneous catalysts are in the same phase (for example, a dissolved catalyst in a liquid reaction mixture).

 Example of Homogeneous catalyst 2 H 2 O 2(aq)+ KI(aq) 2 H 2

Example of Homogeneous catalyst 2 H 2 O 2(aq)+ KI(aq) 2 H 2 O(l)+O 2(g) Example of Heterogeneous catalyst Decomposition of H 2 O 2 in presence of Mn. O 2 Hydrogen peroxide is a solution while manganese dioxide is a solid and can be easily separated.

Home work Term review all Page 614 13, 22, 23 and 25 Test prep

Home work Term review all Page 614 13, 22, 23 and 25 Test prep all