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.

5310 TOTAL ORGANIC CARBON

CopyRight

5310 A. Introduction References
1. Karanfil T, Erdogan I, Schlautman MA. Selecting filter membranes for measuring DOC and UV254. J. Am Water Works Assoc. 2003;95(3):86100. Google Scholar
5310 A. Introduction Bibliography
Fredericks AD. Concentration of organic carbon in the Gulf of Mexico. Rep. 68–27T, Office of Naval Research; 1968. Google Scholar
Williams PM. The determination of dissolved organic carbon in seawater: A comparison of two methods. Limnol Oceanogr. 1969;14:297. Google Scholar
Croll BT. Determination of organic carbon in water. Chem Ind (London). 1972;110:386. Google Scholar
Sharp J. Total organic carbon in seawater–comparison of measurements using persulfate oxidation and high temperature combustion. Mar Chem. 1973;1(3):211229. Google Scholar
Takahashi Y. Analysis techniques for organic carbon and organic halogen. In: Proceedings of the EPA/NATO-CCMS Conference on Adsorption Techniques. Reston (VA); 1979. Google Scholar
Standing Committee of Analysts, National Water Council. The instrumental determination of total organic carbon, total oxygen demand and related determinands. London, UK: Her Majesty’s Stationery Office; 1979. Google Scholar
Kaplan LA. Comparison of high-temperature and persulfate oxidation methods for determination of dissolved organic carbon in freshwaters. Limnol Oceanogr. 1992;37(5):11191125. Google Scholar
Benner R, Hedges JI. A test of the accuracy of freshwater DOC measurements by high-temperature catalytic oxidation and UV-promoted persulfate oxidation. Marine Chem. 1993;41(1-3):161165. Google Scholar
Wangersky PJ. Dissolved organic carbon methods: A critical review. Marine Chem. 1993;41(1–3):6174. Google Scholar
Hutte R, Godec R, O’Neill K. Transferring NASA-sponsored advances in total organic carbon measurement to industrial applications. Microcontamination. 1994;12(4):21. Google Scholar
Kaplan LA. A field and laboratory procedure to collect, process, and preserve freshwater samples for dissolved organic carbon analysis. Limnol Oceanogr. 1994;39(6):14701476. Google Scholar
Aiken G, Kaplan LA, Weishaar J. Assessment of relative accuracy in the determination of organic matter concentrations in aquatic systems. J Environ Monit. 2002:4:7074. Google Scholar
Potter BB, Wimsatt JC. Method 415.3, Rev. 1.2. Determination of total organic carbon and specific UV absorbance at 254 nm in source water and drinking water. Washington DC: U.S. Environmental Protection Agency; 2009. Google Scholar
5310 B. High-Temperature Combustion Method Reference
1. ASTM D7573-18ae1. Standard test method for total carbon and organic carbon in water by high temperature catalytic combustion and infrared detection. West Conshohocken (PA): ASTM International; 2019. Google Scholar
5310 B. High-Temperature Combustion Method Bibliography
Van Hall CE, Barth D, Stenger VA. Elimination of carbonates from aqueous solutions prior to organic carbon determination. Anal Chem. 1965;37(6):769771. Google Scholar
Busch AW. Energy, total carbon, and oxygen demand. Water Resource Res. 1966;2(1):5969. Google Scholar
Blackmore RH, Voshel D. Rapid determination of total organic carbon (TOC) in sewage. Water Sewage Works. 1967;114:398401. Google Scholar
American Society for Testing & Materials. Standard test method for total organic carbon in water; D2579-93. In: Annual Book of ASTM Standards. West Conshohocken (PA): ASTM International; 1994. Google Scholar
5310 C. Persulfate-Ultraviolet or Heated-Persulfate Oxidation Method Reference
1. American Society for Testing & Materials. Standard test method for total carbon in water by ultraviolet, or persulfate oxidation, or both, and infrared detection; D4839-88. In: Annual Book of ASTM Standards. West Conshohocken (PA): ASTM International; 1994. Google Scholar
5310 C. Persulfate-Ultraviolet or Heated-Persulfate Oxidation Method Bibliography
Beattie J, Bricker C, Garvin D. Photolytic determination of trace amounts of organic material in water. Anal Chem. 1961;33:1890. Google Scholar
Armstrong FAJ, Williams PM, Strickland JDH. Photooxidation of organic matter in sea water by ultraviolet radiation, analytical and other applications. Nature 1966;211:481483. Google Scholar
Bramer HC, Walsh MJ, Caruso SC. Instrument for monitoring trace organic compounds in water. Water Sewage Works. 1966;113:275278. Google Scholar
Dobbs RA, Wise RH, Dean RB. Measurement of organic carbon in water using the hydrogen flame ionization detector. Anal Chem. 1967;39(11):12551258. Google Scholar
Montgomery HAC, Thom NS. The determination of low concentrations of organic carbon in water. Analyst. 1962;87(1038):689697. Google Scholar
Armstrong FAJ, Tibbitts S. Photochemical combustion of organic matter in sea water for nitrogen, phosphorus and carbon determination. J Mar Biol Assoc UK. 1968;48(1):143152. Google Scholar
Jones RH, Dageford AF. Application of a high sensitivity total organic carbon analyzer. Proc Instr Soc Amer. 1968;6:43. Google Scholar
Takahashi Y, Moore RT, Joyce RJ. Direct determination of organic carbon in water by reductive pyrolysis. Internatl Lab USA. 1972;4:2128. Google Scholar
Collins KJ, Leb PJ. Williams. An automated photochemical method for the determination of dissolved organic carbon in sea and estuarine waters. Marine Chem. 1977;5(2):123141. Google Scholar
Gravelet-Blondin LR, Van Vliet HR, Mynhardt PA. An automated method for the determination of dissolved organic carbon in fresh water. Water SA. 1980;6(3):138143. Google Scholar
Oake RJ. A Review of photo-oxidation for the determination of total organic carbon in water; technical report. (TR 160). Medmenham (England): Water Research Center; 1981. Google Scholar
Van Steenderen RA, Lin JS. Determination of dissolved organic carbon in water. Anal Chem. 1981;53(13):21572158. Google Scholar
Aiken GR. Chloride interference in the analysis of dissolved organic carbon by the wet oxidation method. Environ Sci Technol. 1992;26(12):24352439. Google Scholar
Godec R, O’Neil K, Hutte R. New Technology for TOC Analysis in Water. Ultrapure Water 1992;9(9):17. Google Scholar
Babatola A, Xu T. Faster and smarter: a BOD-to-TOC conversion enables quick response to process control needs. Water Env Lab Solutions. 2010;17(5):7. Google Scholar
5310 E. Supercritical Water Oxidation Method References
1. Barner H, Huang C, Johnson T, Jacobs G, Martch M, Killilea W. Supercritical water oxidation: An emerging technology. J Hazardous Materials. 1992;31(1):117. Google Scholar
2. Crooker P, Ahluwalia K, Fan Z, Prince J. Operating results from supercritical water oxidation plants. Ind Eng Chem Res. 2000;39(12):48654870. Google Scholar
3. Kritzer P, Dinjus E. An assessment of supercritical water oxidation (SCWO): Existing problems, possible solutions and new reactor concepts. Chem Eng J. 2001;83(3):207214. Google Scholar
4. Standard Methods validation report for the Sievers InnoVox laboratory TOC analyzer. Boulder (CO): Suez Water Technologies & Solutions; [DATE]. Google Scholar

Related

No related items

TAGGED IN:

  • Chemical

TOOLS

CITATION

Standard Methods Committee of the American Public Health Association, American Water Works Association, and Water Environment Federation. 5310 total organic carbon 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.2882.104

SHARE

FROM THE DISCUSSION FORUM: