I either disagree with (or misunderstand) this sentence. Would you mind clarifying?
Now that I have responded to the "causal closure" issue in brief above, I can dedicate a post to this matter.
I’ll start with the highlights of the summary of the cliff’s notes version of the answer I was writing before I realized it was already several pages and I hadn’t even reached in the of the prologue/preface component.
Determinism in classical physics is typically related to (and also taken to be described by) the fact that systems in classical physics are governed by laws encoded in (systems of) differential equations that possess (or are usually assumed to, with notable exceptions dominating certain areas in the literature such as Norton’s dome) unique solutions corresponding to unique trajectories either in “real” space or an abstract space (e.g., phase space) that is reducible to “real” space. The unique trajectory can only exist if there is a unique solution, and unique solutions require that one specify initial conditions (and/or boundary conditions).
So, determinism in classical physics depends upon specifying the initial conditions of a physical system and the assumption that the system is isolated (which relates to the ways in which boundary conditions are employed, among other things). This in turn relates both to the structure of physical theories and to the nature of experiments in physics.
In simple terms, what deterministic laws or behavior or phenomena boils down to from an empirical, experimental perspective is something like the following: if I set up experiments in roughly the same way at arbitrary times and places (that are made arbitrary by freedom of choice), and I have some system under investigation that is supposed to follow known dynamical laws (such as the laws of classical mechanics), then specifying the way I set-up my experiment and prepare my system corresponds to the initial conditions and/or boundary conditions of the dynamical (differential) equations. The determinism of classical physics is class of dynamical laws with equations of motions and so forth that allow me to state that, given a particular experimental set-up and state preparation, the evolution of the system will be such that if (theoretically) I know exactly the necessary values to plug into the dynamical laws governing my system together with either the fact that my experimental arrangement is more or less just that I have ensured the system is approximately isolated or I have ensured this and taken into account other important factors via boundary terms or something similar, then the state of my system after I let it evolve in time will correspond exactly to the mathematical solution for the system’s evolution.
In practice, of course, we never have precise knowledge of the relevant variables, and while we can generally ensure that a unique solution exists formally, almost all the time the solutions for real-world systems must be obtained computationally to some desired degree of accuracy.
But the point is that determinism in physics is generally taken to correspond to, and to be a result of, the fact that the laws of classical physics are of this type: given initial conditions/boundary conditions together with state specification, the evolution of the system in time is determined arbitrarily far into the future (provided it is isolated).
But in a deterministic universe, none of this makes any sense. First, it is nonsense to speak of initial conditions because there is at most one in a deterministic universe (if that universe had a beginning). Second, we can’t repeat experiments because the logic underlying the validity of inferences from such replication and reproducibility is altogether absent without any sort of experimental freedom of choice. Third, a prerequisite for the validity of classical laws in physics is the isolation of the system, which always approximate and corresponds not to universal determinism but the ability to show that under the same sorts of conditions the same sorts of systems will evolve dynamically in the same manner (in theory, at least).
This is not to say that the founders and great names in classical physics would have regarded determinism in this manner. They absolutely didn’t, as for one thing deterministic physics stopped making much sense in the 1800s when the notion that atomic primitives could make up the whole of a unified physics went drastically downhill. Even so, Galileo, Descartes, Newton, Leibniz, Euler, and others engaged in the new science of mechanics were typically making philosophical or even theological arguments about the universe that involved a Designer. Even for those who were not believers or did not invoke God, notions about a mechanical, deterministic universe were still very much metaphysical speculations that tended to become very much in doubt long before the advent of quantum mechanics (for a freely available, recent historical review, see e.g., “
Was physics ever deterministic? The historical basis of determinism and the image of classical physics”
This is why, in quantum foundations, a new term had to be introduced to describe an approach to physical theories and experiments in which determinism applied also to all experiments and experimentalists. And even then, this new term (superdeterminism) and the loophole this potential “solution” is supposed to address (“free choice” or “freedom of choice”) is often addressed in terms of statistical independence, which is one way freedom of experimenters enters into the scientific practice more generally. Taken to the extreme, there is no possible way to close this loophole nor confirm superdeterminism, because the outcome of every experiment is predetermined by conditions over which we have no control at all and about which we would like to believe we do, as this is what makes physics (and empirical inquiry) possible:
"The condition that the choice of the experiments is taken to be a free one means that the experimentalist must be thought to be able to choose them at will, without being unconsciously forced to one or the other choice by some hidden determinism. This condition has an important role in the proof of the theorem. It is often left implicit because of its apparent obviousness. Here it is explicitly stated.
But let it be observed that, when all is said and done, it appears as constituting the very condition of the possibility of any empirical science.”
(emphasis added, p. 64)
d'Espagnat, B. (2006). On Physics and Philosophy. Princeton University Press
