Students of soil science are taught that to determine the amount of soil organic matter, soil organic carbon is measured usually by wet oxidation using potassium dichromate (called Walkley-Black method) or in well-equipped laboratories, using CN analyzer and then multiplied by a conversion factor of 1.72 or 1.724. Most textbooks and laboratory manuals do not explain how this factor was obtained, so students generally accept the value without any question just like they do with other constants used in natural sciences.
Origin of the conversion factor
The conversion factor has a very long history and has practically survived the test of time and modern analytical methods. It is about 150 years old. It was based on studies in the 1820s by the famous agricultural chemist, Carl Sprengel of Goettingen University, that organic matter contains 58 percent carbon. But it was another leading agricultural chemistry pioneer, Emil Wolff from Hohenheim, who introduced the value of 1.724 in 1864. Since then this conversion factor has become universal despite the many later studies showing that it is too low for most soils and that a value of 2.0 is more accurate (Pribyl, 2010). When I was doing my master thesis at IRRI in the late 1980s, Dr. H.U. Neue, the head of the Soils Department and a leading expert on the organic matter of submerged soils, required us to use a factor of 2.0.
Oldest records of the conversion factor (Source: Pribyl, 2010) |
In an excellent review of this conversion factor, Pribyl (2010) concluded that convenience, authority, and tradition rather than the strength of evidence are in large part the reason for the widespread acceptance of the conversion factor until now. However, this may be a controversial conclusion for other soil scientists in some countries. In France for instance, analytical laboratories use a factor of 1.72 or 2.0. The former (i.e. 1.72) is better suited for cultivated horizons while the latter (i.e. 2.0) is more appropriate for forest topsoils (Baize, 1988).
Dr. Emil von Wolff (30 Aug 1818-26 Nov 1896) was a professor of chemistry and agricultural chemistry at the Hohenheim Academy of Agriculture and Forestry in Stuttgart, Germany (since 1967 named University of Hohenheim) from 1853 to 1894. Wolff was one of the agricultural chemistry pioneers who made major contributions to its development and to that of soil science, plant science, and animal science.
Prof. Emil Wolff (Source: Hohenheim Univ) |
Emil von Wolff started his studies in medicine at Kiel University in northern Germany but later shifted to natural science which he finished in Berlin. He obtained his PhD in 1843 in Berlin a year after Justus von Liebig published his most important book on agricultural chemistry. This probably influenced him to focus his teaching and research on soil and plant chemistry as well as on the composition of organic substances including foods. He wrote several books among which were the “Textbook of Agricultural Chemistry (1847)” and “Ash Analysis of Agricultural Products (1877).
Wolff belonged to the most influential and highly regarded agricultural scientists of the 19th century and had no doubt contributed to the fame of the Hohenheim school. It is thus a fitting tribute that an important street at the heart of the Hohenheim University campus bears his name: Emil-Wolff-Strasse (Emil Wolff street).
Baize D. 1988. Soil Science Analyses. John Wiley & Sons, Chichester.
Leisewitz, C. 1910.Wolff, Emil von. In: Allgemeine Deutsche Biographie 55 (1910), S. 115-117 [Onlinefassung]; URL: http://www.deutsche-biographie.de/pnd115599533.html?anchor=adb
Pribyl D.W. 2010. A critical review of the conventional SOC to SOM conversion factor. Geoderma 156: 75-83
VICTOR:
ReplyDelete"Most textbooks and laboratory manuals do not explain how this value was obtained, so students generally accept the value without any question just like they do with other constants used in natural sciences."
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Very insightful Victor and this is not just the problem specifically wit Soil Sciences, but almost all sciences. The problem with mosrden education is that students are trained to read and study answers in text books and become good test takers. Why not train them to be good thinkers, explorers, meditators(not that empty headed type) and DOERS.
When and if they can actually think, ponder and meditate on information absorbed and apply practical applications as a means of further study and observation, then progress of understanding will come about. Otherwise the same failed flaws from Textbooks get repeated generation after generation. I find many things that I learned about Seed Germination from the 1970s still being practiced today and by prominent intitutions. I'm about to write a piece on this because it's inexcusable.
Jess (Soilduck) reader of your posts here here just recently mentioned finishing up on PhD thesis and the hope of educating others, especially younger ones. I think that's wonderful, but I encourage him to be successful, to find common ground words/terms & illustrations which will help the average man/woman who truly need to understand how the natural world works in order to heal the damage done by outdated and malpractice flawed science-based technologies. Speaking down to the average Farmer, gardener, etc will never accomplish good results and these people who have far more effect on our planet than the handful of intellectuals writing papers to impress colleagues & Peers is never going to benefit our planet.
BTW, here's an interesting piece just today!
Studying soil to predict the future of earth's atmosphere
Thanks again for another informative article of the history of such a discipline's background.
Kevin
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Thanks again Kevin for your very informative comment.
ReplyDeleteThis blog is very nice and informative about Structural Soil Cells.
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