All galactic systems that can be modeled by the Henon-Heiles system with low energies tend to exhibit regular and predictable motion;The mathematical explanation of these claims involves an analysis of the structure of the phase spaces of a Henon-Heiles system via Poincare maps. As the energy of such a system is increased, the structure changes and the system can be seen to become more chaotic.
All galactic systems that can be modeled by the Henon-Heiles system with high energies tend to exhibit chaotic and unpredictable motion.
For me, the central philosophical innovation of the paper is the focus on explanatory power, and the claim that even if a nominalistic theory can represent the phenomena in question, the nominalistic theory lacks the explanatory power of the mathematical theory. This is an intriguing claim which seems to me to be largely correct. Still, one would want to know what the source of the explanatory power really is. Lyon and Colyvan focus on the modal aspects of the representation, and claim that this is what would be missing from a nominalistic theory. But it seems that a Field-style theory would have similar problems handling cases of stability analysis where phase spaces are absent. For example, I have used the example of the Konigsberg bridges where the topology of the bridges renders certain sorts of paths impossible. There is of course a modal element in talking of impossible paths, but the non-actual paths are not part of the representation in the way that they appear in phase spaces. What the bridges have in common with this case is that a mathematical concept groups together an otherwise disparate collection of physical phenomena. While all these phenomena may be represented nominalistically, there is something missing from this highly disjunctive representation. I am not sure if what is lost is best characterized as explanatory power, but something is surely worse.
Three different elements come together, then, in Lyon and Colyvan’s case, and it is not clear which contribute to explanatory power: (i) non-actual trajectories in a phase space, (ii) a mathematical concept that groups together a variety of physical systems (“the Henon-Heiles system”) and (iii) stability analysis. Maybe they all make a contribution, but more examples are needed to see this.
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In my view (i) contributes to explanatory power in virtue of providing answers to counterfactual questions concerning how things would have happened differently under different physical configurations (in the way specified by Hitchcock and Woodward), while (ii) contributes to explanatory power in virtue of maximising the range of possible physical systems to which a particular explanation would apply.
(I have a draft paper defending this conception of explanatory depth, which I can send to anyone who is interested).
Thanks for the comment -- I'd be interested in seeing the draft. If you send it to me I can add a link to it here in the comments section (pincock at purdue dot edu).
I've now sent the draft to Chris and can send it to anyone else who is interested (my email can be found by clicking on my name). It'll appear online once it has been polished up a little!
Ken Manders briefly develops a similar sort of criticism in his JSL review of Field's Science without Numbers. His focus is on how the mathematical formulation helps us think about things, like physical space, and the nominalist version renders it difficult if not impossible to explain how we can effectively think and theorize about physics. This is a bit different than what it sounds like was developed in the paper in the post, but it might dovetail.
Shawn, thanks for the reference. I have read many reviews of Field's book, but somehow missed this one. The reference is JSL 49: 303-306. It is worth distinguishing between explaining a physical phenomenon and explaining how scientists can explain that phenomenon. I am inclined to think math is needed for the first, but I am not sure about the second.
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