The Quantum Measurement Problem and Decoherence

In summary, Brian Greene's book "The Fabric of the Cosmos" discusses the concept of decoherence and how it relates to the Quantum Measurement Problem and different interpretations of Quantum Mechanics. Decoherence suggests that the collapse of the probability wave is caused by the interaction of matter and energy, rather than conscious observation. However, decoherence does not fully solve the measurement problem and still requires the use of the Probability Projection. The concept of density operators and statistical mixtures is also explored, with decoherence being a mathematical observation in Unitary Quantum Mechanics. In the end, decoherence confirms that the commonly used method of applying the Probability Projection to calculate probabilities is accurate, regardless of whether the QM description of the measurement apparatus and environment is taken into account
  • #1
Glenn
Hi,
I am reading Brian Greene's new book "The Fabric of the Cosmos".

In the book, Brian Greene talks about the Quantum Measurement Problem, different interpretations of QM, decoherence, etc...

Rather than attributing the collapse of the probability wave to things like conscious or human observation, the book talks about matter and energy interacting with matter as causing its decoherence.

First off, am I understanding it correctly?

If so, isn't it basically saying that everything is built upon and dependant upon everything else?

If so, where and/or when did the initial decoherence take place that caused everything else's probability wave to collapse? Could the Big Bang have been the collapse of the universe's probability wave? Does the question of where and/or when even have any meaning in such a universe?

Thanks for any help or insight into making sense of all this.

-Glenn
 
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  • #2
Dechoherence does not completely solve the measurement problem. At least that is the growing consensus amongst physicists who actually understand the measurement problem. The simple reason is that you still have a superposition state if you also include the environment in your description.

That is not to say that decoherence doesn't offer some useful insights. In fact, most interpretations of QM require decoherence as a component of the resolution of the measurement problem, but it cannot solve it on its own.
 
  • #3
slyboy said:
The simple reason is that you still have a superposition state if you also include the environment in your description.
That is not to say that decoherence doesn't offer some useful insights.

The way I understand it (I'm not really an expert, but have been studying decoherence for a while now) is the following, and feel free to comment, correct, etc... on it.
In the following, I'll try to make a distinction between what I'd call "unitary quantum mechanics" (UQM) and "the probability projection"(PP). Unitary quantum mechanics is the whole of quantum mechanics, with the state space and schroedinger evolution, but without a link to the probabilistic interpretation, which is added as an extra piece, which I call the "probability projection", or "collapse of the wave function" or whatever. This is the heart of the so-called "measurement problem" of quantum mechanics.
All of textbook quantum mechanics is unitary quantum mechanics, but in the end, when you have to calculate probabilities for experimental outcomes, you suddenly have to apply the "probability projection" which is a non-unitary operation and can hence not be explained by a schroedinger evolution.

The concept of the density operator rho in quantum mechanics mixes the two concepts of UQM and PP in a subtle way. A 'pure state' in UQM can be represented by a density operator rho = |state><state|. This is just another mathematical way of writing down a state. However, one can also make "weighted combinations" of states rho = sum_i p_i rho_i with p_i the classical probabilities of a statistical ensemble. This is, strictly speaking, still compatible with UQM. The extension of the notion of physical state of a system to include not only pure states (the Hilbert space) but also these statistical ensembles (mixtures) is then formalized by these rho-operators, but as such the only probabilities that we deal with are "classical" ensemble probabilities. However, there's a hic. With DIFFERENT statistical mixtures can correspond a same rho operator. When now assuming the PP (probability projection) in quantum mechanics, we can show that these apparently different statistical mixtures are experimentally indistinguishable, meaning, they give rise to exactly the same expectation values for all possible observables. But in order to establish that, it is, as I said, necessary to assume the PP idea.

We can hence say that the rho operator for pure states is still a UQM concept, but that the general rho operator describing a mixture needs, in order to be usefull to calculate expectation values (and hence physically describing a state) the PP.

If we consider two quantum systems (hilbert space is direct product of H1 and H2) and we consider observables A1,... which only relate to the first system, then the expectation values of A1... for a general mixture rho can be calculated using only rho1 which is nothing else but tr_2(rho) (this notation means that we take the trace over the second hilbert space of rho).
So rho_1 contains already all the information we need to calculate ANY expectation value of measurements which are only concerned with the first system. Note that in order to have a meaning, we need the PP: otherwise a rho-operator cannot give rise to an expectation value.

Decoherence now. Decoherence theory is nothing else but a mathematical observation in UQM. If we consider a simple quantum system, coupled to a complicated quantum system (the "measurement apparatus" or the "thermal environment"), and we start with a pure product state, and we consider a coupling term in the overall hamiltonian, then very quickly the system evolves into an entangled state according to UQM (so far, no surprises). An entangled, but a pure state.
If we now limit ourselves to observables on the simple system, we can trace out the environment to produce a rho-operator in the "simple system".
Well, it now turns out that this rho-operator becomes diagonal in a VERY short time in a special basis called the coherent states, and that the diagonal components are nothing else but the probabilities we would have calculated using the PP without taking into account the quantum behaviour of the measurement apparatus or the environment. But remember, that to do so, we needed the PP !

So decoherence explains the fact that what we do according to textbook QM, namely, restrict ourselves to the simple system, not consider any QM description of the measurement apparatus, but at the end of the day, apply the PP to the simple system and calculate probabilities of measurement outcomes, is correct, and that it doesn't matter if we would have taken into account the QM description of the measurement apparatus and environment, because, after a lot of complicated calculations, we would have found the same thing.
It also indicates what are the "robust states" in an environment: the so-called coherent states. They are, not surprisingly, the closest descriptions in QM of classical states (particles at a certain position and momentum, with small errors etc...).

What decoherence DOESN'T explain is the PP, because it needs it. However, it somehow justifies the use of the PP in that it shows that it is consistent.
The problem decoherence teaches us is that probably, we'll never find out exactly WHEN the PP has to be applied - if ever, because apparently the result of applying the PP at a high level (after entanglement with the environment) or at a low level (at the level of the measurement) gives us the same expectation values.

Here I've written down my own personal understanding of what decoherence means. Probably it is not complete, maybe wrong, so it would be interesting to discuss it...

cheers,
Patrick.
 
  • #4
Since the PP seems to be only needed by us - humans - in order to do our calculation thing, is it plausible that physics going on where there are no humans, such as the heart of the sun, would go on unitarily? Developing those coherent states?
 
  • #5
vanesch said:
Well, it now turns out that this rho-operator becomes diagonal in a VERY short time in a special basis called the coherent states, and that the diagonal components are nothing else but the probabilities we would have calculated using the PP without taking into account the quantum behaviour of the measurement apparatus or the environment.

I mixed up two things. The coherent states are what results when we consider the system and a "thermal bath". If we consider the measurement apparatus, the rho operator becomes diagonal in the states that correspond to the measurement at hand (if it is a position measurement, it becomes diagonal in the position basis, if it is an angular momentum measurement, it becomes diagonal in the eigenstates of Lz).

In fact, both are related. The "coherent states" of a measurement apparatus (which is ALWAYS connected to a thermal bath because of its macroscopicity) are nothing else but the "pointer" states, corresponding, after having had the "measurement hamiltonian" in action, the eigenstates of the operator that corresponds to the measurement we are performing with the apparatus at hand.

sorry for the confusion.
cheers,
Patrick.
 
  • #6
selfAdjoint said:
is it plausible that physics going on where there are no humans, such as the heart of the sun, would go on unitarily? Developing those coherent states?

If I'm not mistaking, that's exactly the point of view of the Many Worlds Interpretation. So it seems that our minds are tracing out a path throughout the miriads of worlds that are open to it. In the frame of the MWI, decoherence explains why each "mind history" seems to be classical, or nearly so. But it doesn't explain WHY we take a specific path.
All "modified quantum mechanics" interpretations take on another point of view, and try to introduce somehow, at some level, an OBJECTIVE projection. Here, decoherence tells us that if the level is high enough (macroscopic enough), we'll never find out where it is.

Or I'm simply wrong.

cheers,
Patrick.
 

1. What is the quantum measurement problem?

The quantum measurement problem refers to the paradoxical nature of quantum mechanics, where the act of measurement or observation can change the behavior of a particle, making it difficult to determine its exact state. This is in contrast to classical mechanics, where the state of a system can be accurately determined through measurement.

2. How does decoherence help solve the quantum measurement problem?

Decoherence is a process by which a quantum system interacts with its environment, causing it to lose its quantum properties and behave more classically. This helps to explain why we only observe macroscopic objects in definite states, as their quantum behavior has been "decohered" by interactions with the environment. Thus, decoherence provides a possible solution to the measurement problem by showing how the classical world emerges from the quantum world.

3. What is the role of the observer in the quantum measurement problem?

In quantum mechanics, the observer plays a crucial role in determining the state of a particle. However, the exact nature of this role is still debated. Some interpretations suggest that the observer has a direct influence on the outcome of a measurement, while others propose that the observer is simply a passive observer of the system's state.

4. Are there any proposed solutions to the quantum measurement problem other than decoherence?

Yes, there are various proposed solutions to the quantum measurement problem, including the Many-Worlds interpretation, which suggests that every possible outcome of a measurement exists in a separate universe. Another solution is the Consistent Histories interpretation, which proposes that the measurement problem arises from the incorrect use of probabilities in quantum mechanics.

5. How does the quantum measurement problem impact our understanding of reality?

The quantum measurement problem challenges our traditional understanding of reality and raises questions about the nature of the universe. It also has implications for fields such as philosophy, psychology, and even consciousness. The search for a satisfactory solution to the measurement problem continues to drive research and debate in the field of quantum mechanics.

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