Pasteur's quadrant
Pasteur's quadrant is a classification of scientific research projects that seek fundamental understanding of scientific problems, while also having immediate use for society. Louis Pasteur's research is thought to exemplify this type of method, which bridges the gap between "basic" and "applied" research.[1] The term was introduced by Donald E. Stokes in his book, Pasteur's Quadrant.[2]
Other quadrants
As shown in the following table, scientific research can be classified by whether it advances human knowledge by seeking a fundamental understanding of nature, or whether it is primarily motivated by the need to solve immediate problems.
Considerations of use? | |||
---|---|---|---|
No | Yes | ||
Quest for
fundamental |
Yes |
Pure basic research |
Use-inspired basic research |
No | – |
Pure applied research |
The result is three distinct classes of research:
- Pure basic research, exemplified by the work of Niels Bohr, early 20th century atomic physicist.
- Pure applied research, exemplified by the work of Thomas Edison, inventor.
- Use-inspired basic research, described here as "Pasteur's Quadrant".
Usage
Pasteur's quadrant is useful in distinguishing various perspectives within science, engineering and technology. For example, Daniel A. Vallero and Trevor M. Letcher in their book Unraveling Environmental Disasters[3] applied the device to disaster preparedness and response. University science programs are concerned with knowledge-building, whereas engineering programs at the same university will apply existing and emerging knowledge to address specific technical problems. Governmental agencies employ the knowledge from both to solve societal problems.[citation needed] Thus, the U.S. Army Corps of Engineers expects its engineers to apply general scientific principles to design and upgrade flood control systems. This entails selecting the best levee designs for the hydrologic conditions. However, the engineer would also be interested in more basic science to enhance designs in terms of water retention and soil strength. The university scientist is much like Bohr, with the major motivation being new knowledge. The governmental engineer is behaving like Edison, with the greatest interest in utility, and considerably less interest in knowledge for knowledge's sake.
The university engineering researcher's interests on the other hand, may fall between Bohr and Edison, looking to enhance both knowledge and utility. It is not likely that many single individuals fall within the Pasteur cell, since both basic and applied science are highly specialized. Thus, modern science and technology employ what might be considered a systems engineering approach, where the Pasteur cell consists of numerous researchers, professionals and practitioners to optimize solutions. Note that modifications to the quadrant model to more precisely reflect how research and development interact continue to be suggested.[4]
References
- ↑ "Request for Research Proposals". Microsoft Research. FAPESP. http://www.fapesp.br/materia/2826.
- ↑ Stokes, Donald E. (1997). Pasteur's Quadrant – Basic Science and Technological Innovation. Brookings Institution Press. pp. 196. ISBN 9780815781776. https://archive.org/details/pasteursquadrant00stok.
- ↑ Vallero, Daniel A.; Letcher, Trevor M. (2012). Unraveling Environmental Disasters. Elsevier Academic Press. ISBN 9780123970268. http://store.elsevier.com/Unraveling-Environmental-Disasters/isbn-9780123973177/.
- ↑ Dudley, John M. (2013). "Defending Basic Research". Nature Photonics 7 (5): 338–339. doi:10.1038/nphoton.2013.105. Bibcode: 2013NaPho...7..338D. https://zenodo.org/record/889776.
Original source: https://en.wikipedia.org/wiki/Pasteur's quadrant.
Read more |