Hydrolysis as a function of pH at 25 [deg]C.

[Title 40 CFR 796.3500]
[Code of Federal Regulations (annual edition) - July 1, 2002 Edition]
[Title 40 - PROTECTION OF ENVIRONMENT]
[Chapter I - ENVIRONMENTAL PROTECTION AGENCY (CONTINUED)]
[Subchapter R - TOXIC SUBSTANCES CONTROL ACT (CONTINUED)]
[Part 796 - CHEMICAL FATE TESTING GUIDELINES]
[Subpart D - Transformation Processes]
[Sec. 796.3500 - Hydrolysis as a function of pH at 25 [deg]C.]
[From the U.S. Government Printing Office]


40PROTECTION OF ENVIRONMENT282002-07-012002-07-01falseHydrolysis as a function of pH at 25 [deg]C.796.3500Sec. 796.3500PROTECTION OF ENVIRONMENTENVIRONMENTAL PROTECTION AGENCY (CONTINUED)TOXIC SUBSTANCES CONTROL ACT (CONTINUED)CHEMICAL FATE TESTING GUIDELINESTransformation Processes
Sec. 796.3500  Hydrolysis as a function of pH at 25 [deg]C.

    (a) Introduction--(1) Background and purpose. (i) Water is one of 
the most widely distributed substances in the environment. It covers a 
large portion of the earth's surface as oceans, rivers, and lakes. The 
soil also contains water, as does the atmosphere in the form of water 
vapor. As a result of this ubiquitousness, chemicals introduced into the 
environment almost always come into contact with aqueous media. Certain 
classes of these chemicals, upon such contact, can undergo hydrolysis, 
which is one of the most common reactions controlling chemical stability 
and is, therefore, one of the main chemical degradation paths of these 
substances in the environment.
    (ii) Since hydrolysis can be such an important degradation path for 
certain classes of chemicals, it is necessary, in assessing the fate of 
these chemicals in the environment, to know whether, at what rate, and 
under what conditions a substance will hydrolyze. Some of these 
reactions can occur so rapidly that there may be greater concern about 
the products of the transformation than about the parent compounds. In 
other cases, a substance will be resistant to hydrolysis under typical 
environmental conditions, while, in still other instances, the substance 
may have an intermediate stability that can result in the necessity for 
an assessment of both the original compound and its transformation 
products. The importance of transformation of chemicals via hydrolysis 
in aqueous media in the environment can be determined quantitatively 
from data on hydrolysis rate constants. This hydrolysis Test Guideline 
represents a test to allow one to determine rates of hydrolysis at any 
pH of environmental concern at 25[deg]C.
    (2) Definitions and units. (i) ``Hydrolysis'' is defined as the 
reaction of an organic chemical with water, such that

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one or more bonds are broken and the reaction products of the 
transformation incorporate the elements of water (H2O).
    (ii) ``Elimination'' is defined in this Test Guideline to be a 
reaction of an organic chemical (RX) in water in which the X group is 
lost. These reactions generally follow the same type of rate laws that 
hydrolysis reactions follow and, thus, are also covered in this Test 
Guideline.
    (iii) A ``first-order reaction'' is defined as a reaction in which 
the rate of disappearance of the chemical substance being tested is 
directly proportional to the concentration of the chemical substance and 
is not a function of the concentrations of any other substances present 
in the reaction mixture.
    (iv) The ``half-life'' of a chemical is defined as the time required 
for the concentration of the chemical substance being tested to be 
reduced to one-half its initial value.
    (v) ``Hydrolysis'' refers to a reaction of an organic chemical with 
water such that one or more bonds are broken and the reaction products 
incorporate the elements of water (H2O). This type of 
transformation often results in the net exchange of a group X, on an 
organic chemical RX, for the OH group from water. This can be written 
as:

RX+HOH>< ROH+HX.

    (A) Another result of hydrolysis can be the incorporation of both H 
and OH in a single product. An example of this is the hydrolysis of 
epoxides, which can be represented by


    (B) The hydrolysis reaction can be catalyzed by acidic or basic 
species, including OH^- and H3O⁼ 
(H⁼). The promotion of the reaction by 
H3O^- or OH^- is called specific acid or 
specific base catalysis, respectively, as contrasted with general acid 
or base catalysis encountered with other cationic or anionic species. 
Usually, the rate law for chemical RX can be written as:

                               Equation 1

-d[RX]/d= = kh[RX]=kA[H⁼] 
    [RX]

+kB[OH^-] [RX]+k^'N 
[H2O] [RX],


where KA, kB and k'N are the second-
order rate constants for acid and base catalyzed and neutral water 
processes, respectively. In dilute solutions, such as are encountered in 
following this Test Guideline, water is present in great excess and its 
concentration is, thus, essentially constant during the course of the 
hydrolysis reaction. At fixed pH, the reaction, therefore, becomes 
pseudo first-order, and the rate constant (kh) can be written 
as:

                               Equation 2

kh=kA [H⁼]+kB 
    [OH^-]+kN,


where kN is the first-order neutral water rate constant. 
Since this is a pseudo first-order process, the half-life is independent 
of the concentration and can be written as:

                               Equation 3

t1[sol]2=0.693/kh.


At constant pH, Equation 1 can be integrated to yield the first order 
rate expression

                               Equation 4

log10C=- (kh t/
    2.303)+log10Co,


where C is the concentration of the test chemical at time t and 
Co is the initial chemical concentration (t=0).
    (C) At a given pH, Equation 2 under paragraph (a)(2)(v)(B) of this 
section contains three unknowns, kA, kB, and 
kN. Therefore, three equations (i.e., measurements at three 
different pH's at a fixed temperature) are required if one wishes to 
solve for these quantities. Making suitable approximations for 
quantities that are negligible, the expressions for kA, 
kB, and kN using values of kh measured 
at pH 3, 7, and 11 are:

                               Equation 5

kA=10³ [kh (3)-kh 
    (7)+10^-4 kh (11)]

kB=10³ [kh (11)-kh 
    (7)+10^-4 kh (3)]

kN=kh (7)-10^-4 [kh 
    (3)+kh (11)]


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The calculated rate constants from equation 5 under this paragraph can 
be employed in equation 2 under paragraph (a)(2)(v)(B) of this section 
to calculate the hydrolysis rate of a chemical at any pH of 
environmental concern.
    (D) The equations under paragraph (a)(2) of this section apply 
whether the test chemical has one or more hydrolyzable groups. In the 
latter case, the rate may be written as:

                               Equation 6

-d[RX]/dt=[lsqb]RX[rsqb]=k2 [RX]+ . . . . 
    +kn

[RX]=(k1+k2+ . . . . . kn) 
    [RX]=kh [RX].


Equation 6 applies to the hydrolysis rate of a molecule having n 
hydrolyzable groups, each of which follows first-order reaction 
kinetics. The measured kh is now the sum of the individual 
reaction rates and is the only rate constant required in this section.
    (3) Principle of the test method. Procedures described in this 
section enable sponsors to obtain quantitative information on hydrolysis 
rates through a determination of hydrolysis rate constants and half-
lives of chemicals at pH 3.00, 7.00, and 11.00 at 25 [deg]C. The three 
measured rate constants are used to determine the acidic, basic, and 
neutral rate constants associated with a hydrolytic reaction. The latter 
constants can then be employed in determining the hydrolysis rates of 
chemicals at any pH of environmental concern at 25 [deg]C.
    (4) Applicability and specificity. There are several different 
common classes of organic chemicals that are subject to hydrolysis 
transformation, including esters, amides, lactones, carbamates, 
organophosphates, and alkyl halides. Processes other than nucleophilic 
displacement by water can also take place. Among these are elimination 
reactions that exhibit behavior similar to hydrolysis and, therefore, 
are also covered in this section.
    (b) Test procedures--(1) Test conditions--(i) Special laboratory 
equipment. (A) A thermostatic bath that can be maintained at a 
temperature of 25[plusmn]1 [deg]C.
    (B) A pH meter that can resolve differences of 0.05 pH units or 
less.
    (C) Stoppered volumetric flasks (no grease) or glass ampoules that 
can be sealed.
    (ii) Purity of water. Reagent-grade water (e.g., water meeting ASTM 
Type IIA standards or an equivalent grade) shall be used to minimize 
biodegradation. ASTM Type IIA water is described in ASTM D 1193-77 
(Reapproved 1983), ``Standard Specification for Reagent Water.'' ASTM D 
1193-77 (Reapproved 1983) is available for inspection at the Office of 
the Federal Register, 800 North Capitol Street, NW., suite 700, 
Washington, DC. This incorporation by reference was approved by the 
Director of the Office of the Federal Register. This material is 
incorporated as it exists on the date of approval and a notice of any 
change in this material will be published in the Federal Register. 
Copies of the incorporated material may be obtained from the Non-
Confidential Information Center (NCIC) (7407), Office of Pollution 
Prevention and Toxics, U.S. Environmental Protection Agency, Room B-607 
NEM, 401 M St., SW., Washington, DC 20460, between the hours of 12 p.m. 
and 4 p.m. weekdays excluding legal holidays, or from the American 
Society for Testing and Materials (ASTM), 1916 Race Street, 
Philadelphia, PA 19103.
    (iii) Sterilization. All glassware shall be sterilized. Aseptic 
conditions shall be used in the preparation of all solutions and in 
carrying out all hydrolysis experiments to eliminate or minimize 
biodegradation. Glassware can be sterilized in an autoclave or by any 
other suitable method.
    (iv) Precautions for volatility. If the chemical is volatile the 
reaction vessels shall be almost completely filled and sealed.
    (v) Temperature controls. All hydrolysis reactions shall be carried 
out at 25 [deg]C ([plusmn]1 [deg]C) and with the temperature controlled 
to [plusmn]0.1 [deg]C.
    (vi) pH conditions. It is recommended that all hydrolysis 
experiments be performed at pH 3.00, 7.00, and 11.00 [plusmn] 0.05 using 
the appropriate buffers described in paragraph (b)(2)(i)(A) of this 
section.
    (vii) Concentration of solutions of chemical substances. The 
concentration of the test chemical shall be less than one-half the 
chemical's solubility in water but not greater than 10^-3 M.

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    (viii) Effect of acidic and basic groups. Complications can arise 
upon measuring the rate of hydrolysis of chemicals that reversibly 
ionize or are protonated in the pH range 3.00 to 11.00. Therefore, for 
these chemicals, it is recommended that these hydrolysis tests be 
performed at pH 5.00, 7.00, and 900[plusmn]0.05 using the appropriate 
buffers described in paragraphs (b)(2)(i) (A) and (B) of this section. 
If a test chemical reversibly ionizes or protonates in the pH range 5.00 
to 9.00, then it is recommended that additional hydrolysis tests should 
be carried out at pH 6.00 and 8.00[plusmn]0.05 using the buffers 
described in paragraph (b)(2)(i)(B) of this section.
    (ix) Buffer catalysis. For certain chemicals, buffers may catalyze 
the hydrolysis reaction. If this is suspected, hydrolysis rate 
determination shall be carried out with the appropriate buffers and the 
same experiments repeated at buffer concentrations lowered by at least a 
factor of five. If the hydrolysis reaction produces a change of greater 
than 0.05 pH units in the lower concentration buffers at the end of the 
measurement time, the test chemical concentrations also shall be lowered 
by at least a factor of five. Alternatively, test chemical 
concentrations and buffer concentrations may both be lowered 
simultaneously by a factor of five. A sufficient criterion for 
minimization of buffer catalysis is an observed equality in the 
hydrolysis rate constant for two different solutions differing in buffer 
or test chemical concentration by a factor of five.
    (x) Photosensitive chemicals. The solution absorption spectrum can 
be employed to determine whether a particular chemical is potentially 
subject to photolytic transformation upon exposure to light. For 
chemicals that absorb light of wavelengths greater than 290 nm, the 
hydrolysis experiment shall be carried out in the dark, under amber or 
red safelights, in amber or red glassware, or employing other suitable 
methods for preventing photolysis. The absorption spectrum of the 
chemical in aqueous solution can be measured under Sec. 796.1050.
    (xi) Chemical analysis of solutions. In determining the 
concentrations of the test chemicals in solution, any suitable 
analytical method may be employed, although methods which are specific 
for the compound to be tested are preferred. Chromatographic methods are 
recommended because of their compound specificity in analyzing the 
parent chemical without interferences from impurities. Whenever 
practicable, the chosen analytical method should have a precision within 
[plusmn]5 percent.
    (2) Preparation--(i) Reagents and solutions--(A) Buffer solutions. 
Prepare buffer solutions using reagent-grade chemicals and reagent-grade 
water as follows:
    (1) pH 3.00: use 250 mL of 0.100M potassium hydrogen phthalate; 111 
mL of 0.100M hydrochloric acid; and adjust volume to 500 mL with 
reagent-grade water.
    (2) pH 7.00: use 250 mL of 0.100M potassium dihydrogen phosphate; 
145 mL of 0.100M sodium hydroxide; and adjust volume to 500 mL with 
reagent-grade water.
    (3) pH 11.00: use 250 mL of 0.0500M sodium bicarbonate; 113 mL of 
0.100M sodium hydroxide; and adjust volume to 500 mL with reagent-grade 
water.
    (B) Additional buffer solutions. For chemicals that ionize or are 
protonated as discussed in paragraph (b)(1)(viii) of this section, 
prepare buffers using reagent-grade water and reagent-grade chemicals as 
follows:
    (1) pH 5.00: use 250 mL of 0.100M potassium hydrogen phthalate; 113 
mL of 0.100M sodium hydroxide; and adjust volume to 500 mL with reagent-
grade water.
    (2) pH 6.00: use 250 mL of 0.100M potassium dihydrogen phosphate; 28 
mL of 0.100M sodium hydroxide; and adjust volume to 500 mL with reagent-
grade water.
    (3) pH 8.00: use 250 mL of 0.100M potassium dihydrogen phosphate; 
234 mL of 0.100M sodium hydroxide; and adjust volume to 500 mL with 
reagent-grade water.
    (4) pH 9.00: use 250 mL of 0.0250M borax (Na2 
B4O7); 23 mL of 0.100M hydrochloric aid; and 
adjust volume to 500 mL with reagent-grade water.
    (C) Adjustment of buffer concentrations. (1) The concentrations of 
all the above buffer solutions are the maximum concentration to be 
employed in carrying out hydrolysis measurements. If the

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initial concentration of the test chemical is less than 10^-3 
M, the buffer concentration shall be lowered by a corresponding amount; 
e.g., if the initial test chemical concentration is 10^-4 M, 
the concentration of the above buffers shall be reduced by a factor of 
10. In addition, for those reactions in which an acid or base is not a 
reaction product, the minimum buffer concentration necessary for 
maintaining the pH within +0.05 units shall be employed.
    (2) Check the pH of all buffer solutions with a pH meter at 25 
[deg]C and adjust the pH to the proper value, if necessary.
    (D) Preparation of test solution. (1) If the test chemical is 
readily soluble in water, prepare an aqueous solution of the chemical in 
the appropriate buffer and determine the concentration of the chemical. 
Alternatively, a solution of the chemical in water may be prepared and 
added to an appropriate buffer solution and the concentration of the 
chemical then determined. In the latter case, the aliquot shall be small 
enough so that the concentration of the buffer in the final solution and 
the pH of the solution remain essentially unchanged. Do not employ heat 
in dissolving the chemical. The final concentration shall not be greater 
than one-half the chemical's solubility in water and not greater than 
10^-3 M.
    (2) If the test chemical is too insoluble in pure water to permit 
reasonable handling and analytical procedures, it is recommended that 
the chemical be dissolved in reagent-grade acetonitrile and buffer 
solution and then added to an aliquot of the acetonitrile solution. Do 
not employ heat to dissolve the chemical in acetonitrile. The final 
concentration of the test chemical shall not be greater than one-half 
the chemical's solubility in water and not greater than 10^-3 
M. In addition, the final concentration of the acetonitrile shall be one 
volume percent or less.
    (3) Performance of the test. Carry out all hydrolysis experiments by 
employing one of the procedures described in this paragraph. Prepare the 
test solutions as described in paragraph (b)(2)(i) of this section at pH 
3.00, 7.00, and 11.00[plusmn]0.05, and determine the initial test 
chemical concentration (Co) in triplicate. Analyze each 
reaction mixture in triplicate at regular intervals, employing one of 
the following procedures:
    (i) Procedure 1. Analyze each test solution at regular intervals to 
provide a minimum of six measurements with the extent of hydrolysis 
between 20 to 70 percent. Rates should be rapid enough so that 60 to 70 
percent of the chemical is hydrolyzed in 672 hours.
    (ii) Procedure 2. If the reaction is too slow to conveniently follow 
hydrolysis to high conversion in 672 hours but still rapid enough to 
attain at least 20 percent conversion, take 15 to 20 time points at 
regular intervals after 10 percent conversion is attained.
    (iii) Procedure 3. (A) If chemical hydrolysis is less than 20 
percent after 672 hours, determine the concentration (C) after this time 
period.
    (B) If the pH at the end of concentration measurements employing any 
of the above three procedures has changed by more than 0.05 units from 
the initial pH, repeat the experiment using a solution having a test 
chemical concentration lowered sufficiently to keep the pH variation 
within 0.05 pH units.
    (iv) Analytical methodology. Select an analytical method that is 
most applicable to the analysis of the specific chemical being tested 
under paragraph (b)(1)(xi) of this section.
    (c) Data and reporting--(1) Treatment of results. (i) If Procedure 1 
or 2 were employed in making concentration measurements, use a linear 
regression analysis with Equation 4 under paragraph (a)(2)(v)(B) of this 
section to calculate kh at 25 [deg]C for each pH employed in 
the hydrolysis experiments. Calculate the coefficient of determination 
(R²) for each rate constant. Use Equation 3 under paragraph 
(a)(2)(v)(B) of this section to calculate the hydrolysis half-life using 
kh.
    (ii) If Procedure 3 was employed in making rate measurements, use 
the mean initial concentration (Co) and the mean 
concentration of chemical (C) in Equation 4 under paragraph (a)(2)(v)(B) 
of this section to calculate kh for each pH used in the 
experiments. Calculate the hydrolysis half-life using kh in 
Equation 3 under paragraph (a)(2)(v)(B) of this section.

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    (iii) For each set of three concentration replicates, calculate the 
mean value of C and the standard deviation.
    (iv) For test chemicals that are not ionized or protonated between 
pH 3 and 11, calculate kA, kB, and kN 
using Equation 5.
    (2) Specific analytical and recovery procedures. (i) Provide a 
detailed description or reference for the analytical procedure used, 
including the calibration data and precision.
    (ii) If extraction methods were used to separate the solute from the 
aqueous solution, provide a description of the extraction method as well 
as the recovery data.
    (3) Test data report. (i) For Procedures 1 and 2, report 
kh, the hydrolysis half-life (t1/2), and the 
coefficient of determination (R²) for each pH employed in the 
rate measurements. In addition, report the individual values, the mean 
value, and the standard deviation for each set of replicate 
concentration measurements. Finally, report kA, 
kB, and kN.
    (ii) For Procedure 3, report kh and the half-life for 
each pH employed in the rate measurements. In addition, report the 
individual values, the mean value, and the standard deviation for each 
set of replicate concentration measurements. Finally, report 
kA, kB, and kN.
    (iii) If, after 672 hours, the concentration (C) is the same as the 
initial concentration (Co) within experimental error, then 
kh cannot be calculated and the chemical can be reported as 
being persistent with respect to hydrolysis.

[50 FR 39252, Sept. 27, 1985, as amended at 53 FR 10391, Mar. 31, 1988; 
53 FR 12526, Apr. 15, 1988; 53 FR 22323, June 15, 1988; 60 FR 34467, 
July 3, 1995]