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What Is Oxidation-Reduction Potential?

Oxidation-reduction potential (ORP) measures a body of water's ability to break down waste and contaminants, with higher ORP values indicating more oxygen and more efficient bacterial decomposition. ORP is lower near bottom sediments due to high bacterial activity. ORP provides information about water quality and pollution levels beyond just oxygen. A higher ORP means contaminants and dead tissues can be "eaten" more effectively, while lower ORP brings increased toxicity and decay. ORP is directly measured in millivolts using an ORP sensor.

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108 views2 pages

What Is Oxidation-Reduction Potential?

Oxidation-reduction potential (ORP) measures a body of water's ability to break down waste and contaminants, with higher ORP values indicating more oxygen and more efficient bacterial decomposition. ORP is lower near bottom sediments due to high bacterial activity. ORP provides information about water quality and pollution levels beyond just oxygen. A higher ORP means contaminants and dead tissues can be "eaten" more effectively, while lower ORP brings increased toxicity and decay. ORP is directly measured in millivolts using an ORP sensor.

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dban21
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Oxidation-Reduction Potential (ORP)

What is oxidation-reduction potential?

Oxidation-reduction potential (ORP) measures the ability of a lake or river to cleanse itself or
break down waste products, such as contaminants and dead plants and animals. When the ORP
value is high, there is lots of oxygen present in the water. This means that bacteria that
decompose dead tissue and contaminants can work more efficiently. In general, the higher the
ORP value, the healthier the lake or river is. However, even in healthy lakes and rivers, there is
less oxygen (and therefore lower ORP values) as you get closer to the bottom sediments (mud;
see the picture below of a lake bottom). This is because there are many bacteria working hard in
the sediments to decompose dead tissue, and they use up a lot of the available oxygen. In fact,
oxygen disappears very quickly in the bottom mud (often within a centimeter or two) and ORP
falls quickly. ORP is measured in addition to dissolved oxygen because ORP can provide
scientists with additional information of the water quality and degree of pollution, if present.
Also, there are other elements that can function like oxygen (in terms of chemistry) and
contribute to increased ORP.

Photo credit: K. Thomason


http://www.flickr.com/photos/kthomason/375296752/in/photostream/

Why does oxidation-reduction potential matter?

ORP depends on the amount of dissolved oxygen that is in the water, as well as the amount of
other elements that function similarly to oxygen. Though not technically correct, oxygen and
other elements that contribute to high ORP effectively help ‘eat’ things that we don’t want in the
water – such as contaminants and dead tissues. When ORP is low, dissolved oxygen is low,
toxicity of certain metals and contaminants can increase, and there is lots of dead and decaying
material in the water that cannot be cleared or decomposed. This is obviously not a healthy
environment for fish or bugs. In healthy waters, ORP should read high between 300 and 500
millivolts. In the North, we might expect low ORP in waters that receive sewage inputs or
industrial waste.

How do we measure oxidation-reduction potential?

ORP is measured directly in the lake or river water that you are investigating using an ORP
sensor. ORP is measured in millivolts (mV) and the more oxygen that is present in the water, the
higher the ORP reading is. ORP can either be above zero or below zero.

References/For More Information

Horne, A. J., and Goldman, C. R. 1994. Limnology, 2nd edition. McGraw-Hill, Inc. 576 pp.

Wetzel, R. G. 1983. Limnology, 2nd edition. Saunders College Publishing. 760 pp.

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