The content presented here represents the most current version of this section, which was printed in the 24th edition of Standard Methods for the Examination of Water and Wastewater.

5530 PHENOLS

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5530 A. Introduction Bibliography
Ettinger MB, Schott S, Ruchhoft CC. Preservation of phenol content in polluted river water samples previous to analysis. J Amer Water Works Assoc. 1943:35(3):299302. Google Scholar
Carter MJ, Huston MT. Preservation of phenolic compounds in wastewaters. Environ Sci Technol. 1978;12(3):309313. Google Scholar
Neufeld RD, Paladino SB. Comparison of 4-aminoantipyrine and gas-liquid chromatography techniques for analysis of phenolic compounds. J Water Pollut Control Fed. 1985;57(10):10401044. Google Scholar
5530 C. Chloroform Extraction Method Bibliography
Scott RD. Application of a bromine method in determination of phenols and cresols. Ind Eng Chem Anal Ed. 1931;3(1):6770. Google Scholar
Emerson E, Beacham HH, Beegle LC. The condensation of aminoantipyrine. II. A new color test for phenolic compounds. J Org Chem. 1943;8(5):417428. Google Scholar
Ettinger MB, Kroner RC. The determination of phenolic materials in industrial wastes. Proceedings of the 5th Industrial Waste Conference, Purdue University; 1949, p. 345. Google Scholar
Dannis M. Determination of phenols by the aminoantipyrine method. Sewage Ind Wastes 1951;23(12):15161522. Google Scholar
Ettinger MB, Ruchhoft CC, Lishka RJ. Sensitive 4-aminoantipyrine method for phenolic compounds. Anal Chem. 1951;23(12):17831788. Google Scholar
Mohler EF Jr, Jacob LN. Determination of phenolic-type compounds in water and industrial waste waters: comparison of analytical methods. Anal Chem. 1957;29(9):13691374. Google Scholar
Burtschell RH, Rosen AA, Middleton FM, Ettinger MB. Chlorine derivatives of phenol causing taste and odor. J Amer Water Works Assoc. 1959;51(2):205214. Google Scholar
Gordon GE. Colorimetric determination of phenolic materials in refinery waste waters. Removal of sulfides by silver nitrate. Anal Chem. 1960;32(10):13251326. Google Scholar
Ochynski FW. The absorptiometric determination of phenol. Analyst. 1960;85:278. Google Scholar
Faust SD, Aly OM. The determination of 2,4-dichlorophenol in water. J Amer Water Works Assoc. 1962;54(2):235242. Google Scholar
Faust SD, Mikulewicz EW. Factors influencing the condensation of 4-aminoantipyrine with derivatives of hydroxybenzene. II. Influence of hydronium ion concentration on absorptivity. Water Res. 1967;1(7):509522. Google Scholar
Faust SD, Anderson PW. Factors influencing the condensation of 4-aminoantipyrine with derivations of hydroxy benzene. III. A study of phenol content in surface waters. Water Res. 1968;2(7):515525. Google Scholar
Smith LS. Evaluation of instrument for the (ultraviolet) determination of phenol in water; EPA-600/4-76-048. Cincinnati (Ohio): U.S. Environmental Protection Agency; 1976. Google Scholar

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Standard Methods Committee of the American Public Health Association, American Water Works Association, and Water Environment Federation. 5530 phenols In: Standard Methods For the Examination of Water and Wastewater. Lipps WC, Baxter TE, Braun-Howland E, editors. Washington DC: APHA Press.

DOI: 10.2105/SMWW.2882.108

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