Book contents
- Frontmatter
- Contents
- Preface
- Notes on the contributors
- Introduction
- PART 1 Cosmology and time's arrow
- PART 2 Quantum theory and time's arrow
- PART 3 Thermodynamics and time's arrow
- 7 The elusive object of desire: in pursuit of the kinetic equations and the Second Law
- 8 Time in experience and in theoretical description of the world
- 9 When and why does entropy increase?
- PART 4 Time travel and time's arrow
- References
- Index
9 - When and why does entropy increase?
Published online by Cambridge University Press: 26 January 2010
- Frontmatter
- Contents
- Preface
- Notes on the contributors
- Introduction
- PART 1 Cosmology and time's arrow
- PART 2 Quantum theory and time's arrow
- PART 3 Thermodynamics and time's arrow
- 7 The elusive object of desire: in pursuit of the kinetic equations and the Second Law
- 8 Time in experience and in theoretical description of the world
- 9 When and why does entropy increase?
- PART 4 Time travel and time's arrow
- References
- Index
Summary
Introduction
Like the Sirens singing to Ulysses, the concept of entropy has tempted many a thinker to abandon the straight and narrow course. The concept is well-defined for chambers of gases. However, the temptation to extend the concept has been all but irresistible. As a result, entropy is used as a metaphor for uncertainty and disorder. We have nothing against such extensions of usage and, in fact, will indulge in it ourselves. However, we do believe that the price of metaphor is eternal vigilance.
One example of the temptation can be found in R. A. Fisher's Genetical Theory of Natural Selection? In the second chapter of that book, Fisher states a result that he dubs the fundamental theorem of natural selection. The theorem states that the average fitness of the organisms in a population increases under selection, and does so at a rate given by the additive genetic variance in fitness. Fisher then proposes the following analogy:
It will be noticed that the fundamental theorem … bears some remarkable resemblances to the second law of thermodynamics. Both are properties of populations, or aggregates, true irrespective of the nature of the units which compose them; both are statistical laws; each requires the constant increase of a measurable quantity, in the one case the entropy of a physical system and in the other the fitness … of a biological population [p. 39].
Fisher then quotes Eddington's famous remark that ‘the law that entropy always increases – the second law of thermodynamics – holds, I think, the supreme position among the laws of nature.’
- Type
- Chapter
- Information
- Time's Arrows TodayRecent Physical and Philosophical Work on the Direction of Time, pp. 230 - 256Publisher: Cambridge University PressPrint publication year: 1995
- 1
- Cited by