In this Book

What Makes a Good Experiment?: Reasons and Roles in Science

Book
Allan Franklin
2016
Published by: University of Pittsburgh Press
summary
What makes a good experiment? Although experimental evidence plays an essential role in science, as Franklin argues, there is no algorithm or simple set of criteria for ranking or evaluating good experiments, and therefore no definitive answer to the question. Experiments can, in fact, be good in any number of ways: conceptually good, methodologically good, technically good, and pedagogically important. And perfection is not a requirement: even experiments with incorrect results can be good, though they must, he argues, be methodologically good, providing good reasons for belief in their results. Franklin revisits the same important question he posed in his 1981 article in the British Journal for the Philosophy of Science, when it was generally believed that the only significant role of experiment in science was to test theories. But experiments can actually play a lot of different roles in science—they can, for example, investigate a subject for which a theory does not exist, help to articulate an existing theory, call for a new theory, or correct incorrect or misinterpreted results. This book provides details of good experiments, with examples from physics and biology, illustrating the various ways they can be good and the different roles they can play.

Table of Contents

restricted access

Front Cover

Half title, Title page, Copyright

Contents

pp. v-vi

Acknowledgments

pp. vii-viii

Introduction

pp. 1-8

Part I. Conceptually Important Experiments: Those That Lead to Significant Changes in Theory

pp. 9-10

1. Gregor Mendel, “Experiments in Plant Hybridization”: The Best Experiments Ever Done!

pp. 11-28

2. The Discovery of Parity Nonconservation

pp. 29-40

3. The Meselson-Stahl Experiment: “The Most Beautiful Experiment in Biology”

pp. 41-56

4. CP or not CP: A Convincing Experiment

pp. 57-68

5. The Nondiscovery of Parity Nonconservation: A Missed Opportunity

pp. 69-80

Part II. Measuring a Quantity of Importance

pp. 81-82

6. Measuring a Quantity of Importance and Testing an Equation: Millikan and Planck’s Constant

pp. 83-111

7. Robert Millikan and the Charge of the Electron

pp. 112-124

Part III. Evidence for Entities

pp. 125-126

8. “Observing” the Neutrino: The Reines-Cowan Experiments

pp. 127-146

9. The Discovery of the η Meson

pp. 147-151

10. Is There a Second Neutrino?

pp. 152-162

11. The Missing Piece of the Puzzle: The Discovery of the Higgs Boson

pp. 163-178

Part IV. Solving a Vexing Problem

pp. 179-180

12. William Wilson and the Absorption of β Rays

pp. 181-196

13. Ellis and Wooster, the Continuous Energy Spectrum in β Decay: Something Is Missing

pp. 197-213

14. The Solar-Neutrino Problem

pp. 214-226

Part V. Measuring Nothing

pp. 227-228

15. The Disappearance of the 17-keV Neutrino

pp. 229-240

16. The Michelson-Morley Experiment

pp. 241-265

17. A Tale of Two Experiments: Is There a Fifth Force?

pp. 266-280

18. The Search for Magnetic Monopoles

pp. 281-295

Conclusion

pp. 296-306

Notes

pp. 307-338

References

pp. 339-358

Index

pp. 359-372

Back cover

Back To Top