How many times do we hear that some scientific view is “only theory” or that it is “not proven”? The hidden implication is that if we have not “proven” the case, then we do not know anything for certain about it, and any idea is as good as any other. A recent and vivid example of this problem is the ongoing argument in the popular media about global warming. Do we need to be absolutely certain before we take action?

These same issues and doubts come up in university science classes for non-science students, and in public lectures with scientific themes. The problem, described by McMaster University astronomer William Harris at this week’s CASCA 2011 meeting in Ontario, Canada, boils down to a misunderstanding about the way science really works. Contrary to the way it is often portrayed in public, science is not about “proving theories”. An effective way to discuss these issues is to imagine a continuous line stretching from “totally right” at the top, to “totally wrong” at the bottom. Any scientific idea, hypothesis, or theory can be located somewhere on that line. If it has a lot of evidence supporting it, it lies near the top (for example, that the Earth is round; or that Newton’s laws of motion are correct; or that DNA is the basis of the genetic code). Old ideas that were disproven sit at the bottom of the line (for example, that dinosaurs coexisted with early humans, or that the Sun revolves around the Earth).

A new scientific idea just beginning to be explored sits somewhere in the middle of the line. As more evidence comes in and our tools for interpretation get better, we might find that the idea is wrong (“disproven”) and it immediately drops to the bottom of the line. But with luck, we might find that it agrees with a lot of evidence and so our confidence in the idea grows. Over time, it might move upward into a full-fledged body of knowledge that is much more secure.

Another way to think about this line is to ask how much you would bet that a given scientific idea or theory is right. We literally bet our lives that Newton’s laws are right, but we wouldn’t be quite that confident in a new and untested statement. The key to understanding science is the role played by constant testing and real-world evidence.

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McMaster University, one of four Canadian universities listed among the Top 100 universities in the world, is renowned for its innovation in both learning and discovery. It has a student population of 23,000, and more than 140,000 alumni in 128 countries.

The University of Western Ontario is proudly hosting the 2011 CASCA conference May 30 to June 2, 2011, in London, Ontario, to celebrate Canadian astronomical and astrophysical research: http://www.casca2011.com/index.html

The Canadian Astronomical Society (http://www.casca.ca) was founded in 1971 and incorporated in 1983 as a society of professional astronomers. The society is devoted to the promotion and advancement of knowledge of the universe through research and education. Membership is open to persons with a professional involvement with these goals in astronomy and the related sciences. The main activities of the Society are its annual scientific meetings, the planning and realization of scientific projects, the support of the scientific activities of its members, and the dissemination of related information among members and other interested persons. The Society supports committees on Optical and Infrared Astronomy, Radio Astronomy, Space Astronomy, Theoretical Astronomy, Education, Heritage, Canadian Grad Students, and Awards. Cassiopeia, the quarterly newsletter of the Society, is published at equinoxes and solstices.

Press Contact:
Leslie Sage
CASCA Press Officer
+1 (301) 675-8957 (cell)
cascapressofficer@gmail.com

Science Contact:
Dr. William Harris
Dept. of Physics and Astronomy
McMaster University,
harris@physics.mcmaster.ca