'''CT Values''' are an important part of calculating disinfectant dosage for the chlorination of drinking water. A CT value is the product of the concentration of a disinfectant (e.g. free chlorine) and the contact time with the water being disinfected. It is typically expressed in units of mg-min/L.
The goal of disinfection is the inactivation of microorganisms. This depends on: the microorganism, the disinfectant being used, the concentration of the disinfectant, the contact time, and the temperature and pH of the water.<ref>{{cite web|last=Pine|first=Rob|title=Everything You Ever Wanted to Know About CT (and then some)|url=http://www.nmenv.state.nm.us/dwb/whats_new/documents/CT.pdf|publisher=New Mexico Environment Department|accessdate=20 October 2013|author2=Joe Savage}}</ref>
==Kinetics== The disinfection kinetics are conventionally calculated via the Chick-Watson model, named for the work of Harriette Chick<ref>{{cite journal|last=Chick|first=Harriette|title=An Investigation of the Laws of Disinfection|journal=The Journal of Hygiene|date=January 1908|volume=8|issue=1|pages=92–158|doi=10.1017/s0022172400006987|pmid=20474353|pmc=2167134}}</ref> and H. E. Watson.<ref>{{cite journal|last=Watson|first=Herbert Edmeston|title=A Note on the Variation of the Rate of Disinfection with Change in the Concentration of the Disinfectant|journal=The Journal of Hygiene|year=1908|volume=8|issue=4|pages=536–42|doi=10.1017/s0022172400015928|pmid=20474372|pmc=2167149}}</ref> This model is expressed by the following equation:<ref name=autogenerated2005>{{cite book|last=MWH|title=Water Treatment: Principles And Design|year=2005|publisher=John Wiley & Sons|location=Hoboken, NJ|isbn=0471110183|edition=2}}</ref>
: <math> \ln(\frac{N}{N_0})=-\Lambda_{CW} C^n t \!</math>
Where: * <math> (\frac{N}{N_0}) \!</math> is the survival ratio for the microorganisms being killed * <math> \Lambda_{CW} \!</math> is the Chick-Watson coefficient of specific lethality * <math> C \!</math> is the concentration of the disinfectant (typically in mg/L) * <math> n \!</math> is the coefficient of dilution, frequently assumed to be 1<ref name="autogenerated2005"/> * <math> t \!</math> is the contact time (typically in minutes or seconds)
The survival ratio is commonly expressed as an inactivation ratio (in %) or as the number of reductions in the order of magnitude of the microorganism concentration. For example, a situation where N<sub>0</sub>=10<sup>7</sup> CFU/L and N=10<sup>4</sup> CFU/L would be reported as a 99.9% inactivation or "3-log<sub>10</sub>" removal.
In water treatment practice, tables of the product C×t are used to calculate disinfection dosages. The calculated CT value is the product of the disinfectant residual (in mg/L) and the detention time (in minutes), through the section at peak hourly flow.<ref>{{cite book|last=Office of Drinking Water|title=Guidance Manual for Compliance with the Filtration and Disinfection Requirements for Public Water Systems Using Surface Water Sources|year=1991|publisher=United States Environmental Protection Agency|url=https://www.epa.gov/sites/default/files/2015-10/documents/guidance_manual_for_compliance_with_the_filtration_and_disinfection_requirements.pdf|quote=page 3-20}}</ref> These tables express the required CT values to achieve a desired removal of microorganisms of interest in drinking water (e.g. ''Giardia lamblia'' cysts) for a given disinfectant under constant temperature and pH conditions. A portion of such a table is reproduced below.
==Example CT Table== CT Values for the Inactivation of Giardia Cysts by Free Chlorine at 5 °C and pH ≈ 7.0:<ref>{{cite book|last=Office of Drinking Water|title=Guidance Manual for Compliance with the Filtration and Disinfection Requirements for Public Water Systems Using Surface Water Sources|year=1991|publisher=United States Environmental Protection Agency|url=https://www.epa.gov/sites/default/files/2015-10/documents/guidance_manual_for_compliance_with_the_filtration_and_disinfection_requirements.pdf|quote=Table E-2}}</ref>
{| class="wikitable" |- ! ''Chlorine Concentration (mg/L)'' ! 1 log inactivation (mg·L<sup>−1</sup>·min) ! 2 log inactivation (mg·L<sup>−1</sup>·min) ! 3 log inactivation (mg·L<sup>−1</sup>·min) |- | ''0.6'' | 48 | 95 | 143 |- | ''1.2'' | 51 | 101 | 152 |- | ''1.8'' | 54 | 108 | 162 |- | ''2.4'' | 57 | 115 | 172 |}
Full tables are much larger than this example and should be obtained from the regulatory agency for a particular jurisdiction.
==See also== * Chlorination * Disinfectant
==References== {{reflist}}
==External links== * {{cite book|last=Earth Tech, Inc.|title=Chlorine and Alternative Disinfectants Guidance Manual|year=2005|publisher=Manitoba Water Stewardship|location=Manitoba|url=https://www.gov.mb.ca/waterstewardship/odw/reg-info/approvals/odw_chlorine_and_alternative_disinfectants.pdf}}
Category:Water treatment Category:Chlorine