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Rate laws may exhibit fractional orders for some reactants, and negative reaction orders are sometimes observed when an increase in the concentration of one reactant causes a decrease in reaction rate. A few examples illustrating these points are provided:

NO 2 + CO NO + CO 2 rate = k [ NO 2 ] 2 CH 3 CHO CH 4 + CO rate = k [ CH 3 CHO ] 2 2N 2 O 5 2NO 2 + O 2 rate = k [ N 2 O 5 ] 2NO 2 + F 2 2NO 2 F rate = k [ NO 2 ] [ F 2 ] 2NO 2 Cl 2NO 2 + Cl 2 rate = k [ NO 2 Cl ]

It is important to note that rate laws are determined by experiment only and are not reliably predicted by reaction stoichiometry.

Reaction orders also play a role in determining the units for the rate constant k . In [link] , a second-order reaction, we found the units for k to be L mol −4 s −1 , whereas in [link] , a third order reaction, we found the units for k to be mol −2 L 2 /s. More generally speaking, the units for the rate constant for a reaction of order ( m + n ) are mol 1 ( m + n ) L ( m + n ) −1 s −1 . [link] summarizes the rate constant units for common reaction orders.

Rate Constants for Common Reaction Orders
Reaction Order Units of k
( m + n ) mol 1 ( m + n ) L ( m + n ) −1 s −1
zero mol/L/s
first s −1
second L/mol/s
third mol −2 L 2 s −1

Note that the units in the table can also be expressed in terms of molarity ( M ) instead of mol/L. Also, units of time other than the second (such as minutes, hours, days) may be used, depending on the situation.

Key concepts and summary

Rate laws provide a mathematical description of how changes in the amount of a substance affect the rate of a chemical reaction. Rate laws are determined experimentally and cannot be predicted by reaction stoichiometry. The order of reaction describes how much a change in the amount of each substance affects the overall rate, and the overall order of a reaction is the sum of the orders for each substance present in the reaction. Reaction orders are typically first order, second order, or zero order, but fractional and even negative orders are possible.

Chemistry end of chapter exercises

How do the rate of a reaction and its rate constant differ?

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Doubling the concentration of a reactant increases the rate of a reaction four times. With this knowledge, answer the following questions:

(a) What is the order of the reaction with respect to that reactant?

(b) Tripling the concentration of a different reactant increases the rate of a reaction three times. What is the order of the reaction with respect to that reactant?

(a) 2; (b) 1

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Tripling the concentration of a reactant increases the rate of a reaction nine times. With this knowledge, answer the following questions:

(a) What is the order of the reaction with respect to that reactant?

(b) Increasing the concentration of a reactant by a factor of four increases the rate of a reaction four times. What is the order of the reaction with respect to that reactant?

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How much and in what direction will each of the following affect the rate of the reaction: CO( g ) + NO 2 ( g ) CO 2 ( g ) + NO( g ) if the rate law for the reaction is rate = k [ NO 2 ] 2 ?

(a) Decreasing the pressure of NO 2 from 0.50 atm to 0.250 atm.

(b) Increasing the concentration of CO from 0.01 M to 0.03 M .

(a) The process reduces the rate by a factor of 4. (b) Since CO does not appear in the rate law, the rate is not affected.

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Practice Key Terms 5

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Source:  OpenStax, Ut austin - principles of chemistry. OpenStax CNX. Mar 31, 2016 Download for free at http://legacy.cnx.org/content/col11830/1.13
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