At the risk of embarrassing myself in the face of what I presume to be a quotation of some eminent physicist
"'The attempt to conceive the quantum-theoretical description as the complete description of the individual systems leads to unnatural theoretical interpretations, which immediately become unnecessary if one accepts the interpretation that the description refers to ensembles of systems and not to individual systems.'
– Albert Einstein
This quotation is perhaps the most famous statement of the ensemble interpretation of quantum mechanics. The role of the ensemble in quantum mechanics ranges from innocuous to profound, and even controversial.
The innocuous role of the ensemble stems from the fact that quantum mechanics does not predict the actual events, but only the probabilities of the various possible outcomes of the various possible events. In order to compare the predictions of quantum mechanics with experiment, one must prepare a state and measure some dynamical variable, and repeat this preparation–measurement sequence many times. The relative frequencies of the various outcomes in this ensemble of results can then be compared with the theoretical probabilities predicted by quantum mechanics. Thus it is natural to say that quantum mechanics describes the statistics of an ensemble of similarly prepared systems."
Greenberger, D., Hentschel, K., & Weinert, F. (2009).
Compendium of Quantum Physics: Concepts, Experiments, History and Philosophy (Springer)
It's the result of calling something "preparation of a system" when one isn't actually doing that: (italics in original):
"The purpose of measurements is the determination of properties of the physical system under investigation. In this sense the general conception of measurement is that of an unambiguous comparison: the object system
S, prepared in a state
T, is brought into a suitable contact - a
measurement coupling- with another, independently prepared system, the
measuring apparatus from which the
result related to the measured observable
E is
determined by reading the value of the
pointer observable. It is the goal of the quantum theory of measurement to investigate whether measuring processes, being physical processes, are the subject of quantum mechanics. This question, ultimately, is the question of the universality of quantum mechanics.
In classical physics all observables are objective in any state, that is, they always assume well-defined though possibly unknown values. Moreover, it is possible in principle to measure them without in any way changing the observed system. Hence the measurement outcome is nothing but the value of the observable
before as well as
after the measurement. On the other hand, in the case of quantum mechanical systems for any observable there exist states in which the observable is not objective. In that case the reading shown by the apparatus cannot refer to an objective value of the observable
before the measurement. Furthermore, it is not evident that a measurement may be such that its outcome refers to an objective value of the observable after the measurement" p.25
Busch, P. Lahti, P.J. Mittelstaedt, P. (1996).
The Quantum Theory of Measurement 2nd Ed. (
Lecture Notes in Physics)
It was my understanding that, in principle, there is a ket which represents the complete microscopic state of a system. Period.
The ket represents the complete state, yes. But under that assumption, it doesn't represent a physical system: "The standard interpretation of QM, tells us nothing about the underlying physics of the system. The state vector represents our knowledge of the system, not its physics".
Caponigro, M. (2010)
Interpretations of Quantum Mechanics: A Critical Survey.
Prespacetime Journal, 1(5): 745-760
Every identically-prepared system would have this same ket
Yes, which is the problem: "The same classical state leads necessarily to the same observable events, but a new preparation of the same quantum state may lead to quite different observable outcomes." from
Compendium of Quantum Physics: Concepts, Experiments, History and Philosophy
and hence there is no need to refer to any 'statistical distribution' if we are simply talking about the complete quantum state.
The complete quantum state is obtained by
premeasurement, which not only means different identically prepared states can yield different results, but also that what we call "preparing" is really something quite different, and depending upon one's lab procedures, the methods (and in particular the mathematical methods) by which the "state" of this singular "system" is transcribed (e.g., via an interaction Hamiltonian) differs, especially when compared to the ways classical systems are transcribed based upon particular features and (obviously) the experimental design. But however this quantum systems are prepared, the "initial state" is always a compound system of repeated preparations of "one" system which isn't one system at all. To call it
an initial system is necessarily a statistical interpretation. The ensemble interpretation is basically a class of interpretations held by those who refuse to call what is clearly multiple systems prepared over and over "the system". It's an objection to the singular idealized abstraction that is obtained through preparing an ensemble of systems. Considering the range of interpretations, with the holographic anthropic multiverse-type interpretations on the one hand, and Einstein's "screw you people- if you want to pretend the moon isn't there when you don't look, go ahead and have fun playing dice with god" take on the other hand, this is definitely closer to Einstein. And while I don't think the versions I've seen really warrant the distinctions made, I do think it's better than making the whole think disappear through largely unfalsifiable appeals to infinite universes and some
ad hoc version of the projection postulate so that one can bypass the measurement problem by stealing everything that went into making QM successful and giving no justification for using these methods.
Is it possible the author of your quotation would not object to what I said, because he is adopting an operational definition of "the state" for the convenience of experimentation?
It's an interpretation (or rather, a class of interpretations) of quantum mechanics, so not really. That is, the way you describe it that I've cut out is pretty accurate, except that it is not convenience at all (anymore than the multiverse interpretation is, at least). For a somewhat outdated but rather thorough treatment (for a paper) see
here. The paper (published in
physics reports) refers to a "modern perspective" (why would anybody title a paper that was guaranteed to become a dated perspective in such a way?), but
Smolin's is
actually modern. However, it's also more exotic. I sometimes think cosmologists are competing with each other to see who can get away with the most bizarre interpretation. Tegmark's solution is a multiverse in which "the 'many-worlds' are all the same".
that mathematical representation has what you call a "one-to-one correspondence" with the system
The statistical nature is a result of the transcription process itself, which relies on theory not just to prepare but to characterize the system. At no time are the specifications of the system ever related to any single physical system nor is it known how the abstract system's description relates to the quantum system. Hence the plethora of interpretations.
Both say in principle that any given physical system has a one-to-one correspondence with its mathematical representation.
Of the classes of interpretations out there, I don't know of one in which this is true. Realists tend to interpret the formalism as the probability of finding a particle, Bohr/Copenhagen/various interpretations of the Copenhagen interpretation all tend to treat the system as nothing more than a mapping from the preparation devices (or, another variant, object-system apparatus state) to the measurement, and say nothing about the physical system other than that it is irreducibly statistical and the formalism is solely a method of obtaining measurements.
