Entanglement (physics)

There are three interrelated meanings of the word "entanglement" in physics. They are listed below and then discussed, both separately and in relation to each other.

• A hypothetical combination of empirical facts incompatible with the conjunction of three fundamental assumptions about nature, called "counterfactual definiteness", "relativistic local causality" and "no-conspiracy" (see below), but compatible with the conjunction of the last two of them ("relativistic local causality" and "no-conspiracy"). Such a combination will be called "empirical entanglement" (which is not a standard terminology).
• A prediction of the quantum theory stating that the empirical entanglement must occur in appropriate physical experiments (below called "quantum entanglement").
• In quantum theory there is a technical notion of "entangled state".

Empirical entanglement

Some people understand it easily, others find it difficult and confusing.

It is easy, since no physical or mathematical prerequisites are needed. Nothing like Newton laws, Schrodinger equation, conservation laws, nor even particles or waves. Nothing like differentiation or integration, nor even linear equations.

It is difficult and confusing for the very same reason! It is highly abstract. Many people feel uncomfortable in such a vacuum of concepts and rush to return to the particles and waves.

The framework, and local causality

The following concepts are essential here.

• A physical apparatus that has a switch and several lights. The switch can be set to one of several possible positions. A little after that the apparatus flashes one of its lights.
• "Local causality": widely separated apparata are incapable of signaling to each other.

Otherwise the apparata are not restricted; they may use all kinds of physical phenomena. In particular, they may receive any kind of information that reaches them. We treat each apparatus as a black box: the switch position is its input, the light flashed is its output; we need not ask about its internal structure.

However, not knowing what is inside the black boxes, can we know that they do not signal to each other? There are two approaches, non-relativistic ("loose") and relativistic ("strict").

The loose approach: we open the black boxes, look, see nothing like mobile phones and rely on our knowledge and intuition.

The strict approach: we do not open the black boxes. Rather, we place them, say, 360,000 km apart (the least Earth-Moon distance) and restrict the experiment to a time interval of, say, 1 sec. Relativity theory states that they cannot signal to each other, for a good reason: a faster-than-light communication in one inertial reference frame would be a backwards-in-time communication in another inertial reference frame!

Falsifiabilty, and no-conspiracy assumption

A claim is called falsifiable (or refutable) if it has observable implications. If some of these implications contradict some observed facts then the claim is falsified (refuted). Otherwise it is corroborated.

The relativistic local causality was never falsified; that is, a faster-than-light signaling was never observed. Does it mean that local causality is corroborated? This question is more intricate than it may seem.

Let A, B be two widely separated apparata, x_A the input (the switch position) of A, and y_B the output (the light flashed) of B. (For now we do not need y_A and x_B.) Local causality claims that x_A has no influence on y_B.

An experiment consisting of n trials is described by x_A(i), y_B(i) for i = 1,2,...,n. Imagine that n = 4 and

x_A(1) = 1,   x_A(2) = 2,   x_A(3) = 1,   x_A(4) = 2,  

y_B(1) = 1,   y_B(2) = 2,   y_B(3) = 1,   y_B(4) = 2.

The data suggest that x_A influences y_B, but do not prove it. Two alternative explanations are possible:

• the B apparatus chooses y_B at random (say, tossing a coin); the four observed equalities y_B(i) = x_A(i) are just a coincidence (of probability 1/16);
• the B apparatus alternates 1 and 2, that is, y_B(i) = 1 for all odd i but y_B(i) = 2 for all even i.

Consider a more thorough experiment: n = 1000, and x_A(i) are chosen at random, say, tossing a coin. Imagine that y_B(i) = x_A(i) for all i = 1,2,...,n. The influence of x_A on y_B is shown very convincingly! But still, an alternative explanation is possible.

For choosing x_A, the coin must be tossed within the time interval scheduled for the trial, since otherwise a slower-than-light signal can transmit the result to the B apparatus before the end of the trial. However, is the result really unpredictable in principle (not just in practice)? Not necessarily so. Moreover, according to classical mechanics, the future is uniquely determined by the past! In particular, the result of the coin tossing exists in the past as a complicated function of a huge number of coordinates and momenta of micro particles.

It is logically possible, but quite unbelievable that the future result of coin tossing is somehow spontaneously singled out in the microscopic chaos and transmitted to the B apparatus in order to influence y_B. The no-conspiracy assumption claims that such exotic scenarios may be safely neglected.

The conjunction of the two assumptions, relativistic local causality and no-conspiracy, is falsifiable, but was never falsified; thus, both assumptions are corroborated.

Below, the no-conspiracy is always assumed (unless explicitly stated otherwise).

Counterfactual definiteness

In this section a single apparatus is considered.

An trial is described by a pair (x,y) where x is the input (the switch position) and y is the output (the light flashed). Is y a function of x? We may repeat the trial with the same x and get a different y (especially if the apparatus tosses a coin). We can set the switch to x again, but we cannot set all molecules to the same microstate. Still, we may try to imagine the past changed, asking a counterfactual question:

• Which outcome the experimenter would have received (in the same trial) if he/she did set the switch to another position?

It is meant that only the input x is changed in the past, nothing else. The question may seem futile, since an answer cannot be verified empirically. Strangely enough, the question will appear to be very useful in the next section.

Classical physics can interpret the question as a change of external forces acting on a mechanical system of a large number of microscopic particles. It is unfeasible to calculate the answer, but anyway, the question makes sense, and the answer exists in principle:

${\displaystyle y=f(x)}$

for some function ${\displaystyle f:X\to Y,}$ where X is the finite set of all possible inputs, and Y is the finite set of all possible outputs. Existence of this function f is called "counterfactual definiteness".

Repeating the experiment we get

${\displaystyle y(i)=f_{i}(x(i))}$

for ${\displaystyle i=1,2,\dots }$ Each time a new function f_i appears; thus x(i)=x(j) does not imply y(i)=y(j). In the case of a single apparatus, counterfactual definiteness is not falsifiable, that is, has no observable implications. Surprisingly, for two (and more) apparata the situation changes dramatically.

Local causality and counterfactual definiteness

For two apparata, A and B, an experiment is described by two pairs, (x_A,y_A) and (x_B,y_B) or, equivalently, by a combined pair ((x_A,x_B), (y_A,y_B)). Counterfactual definiteness alone (without local causality) takes the form

${\displaystyle (y_{\rm {A}},y_{\rm {B}})=f_{\rm {A,B}}(x_{\rm {A}},x_{\rm {B}})}$

or, equivalently,

${\displaystyle y_{\rm {A}}=f_{\rm {A}}(x_{\rm {A}},x_{\rm {B}}),}$   ${\displaystyle y_{\rm {B}}=f_{\rm {B}}(x_{\rm {A}},x_{\rm {B}}).}$

Assume in addition that A and B are widely separated and the local causality applies. Then x_A cannot influence y_B, and x_B cannot influence y_A, therefore

${\displaystyle y_{\rm {A}}=f_{\rm {A}}(x_{\rm {A}}),}$   ${\displaystyle y_{\rm {B}}=f_{\rm {B}}(x_{\rm {B}}).}$

An alternative language is logically equivalent, but makes the presentation more vivid. Imagine an experimenter, Alice, near the apparatus A, and another experimenter, Bob, near the apparatus B. Alice is given some input x_A and must provide an output y_A. The same holds for Bob, x_B and y_B. Once the inputs are received, no communication is permitted between Alice and Bob until the outputs are provided. The input x_A is an element of a prescribed finite set X_A (not necessarily a number); the same holds for y_A and Y_A, x_B and X_B, y_B and Y_B.

It may seem that the apparata A, B are of no use for Alice and Bob. Significantly, this is an illusion.

Example, as last

The simplest example of empirical entanglement is presented here. First, its idea is explained informally.

Alice and Bob pretend that they know a 2x2 matrix

${\displaystyle {\begin{pmatrix}a&b\\c&d\end{pmatrix}}}$

consisting of numbers 0 and 1 only, satisfying four conditions:

${\displaystyle a=b,\quad c=d,\quad a=c,\quad b\neq d.}$

Surely they lie; these four conditions are evidently inconsistent. Nevertheless Alice commits herself to show on request any row of the matrix, and Bob commits himself to show on request any column. We expect the lie to manifest itself on the intersection of the row and the column (not always but sometimes). However, Alice and Bob promise to always agree on the intersection!

External links

Wikipedia

Counterfactual definiteness

Falsifiability

Laplace's demon

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Quantum entanglement is probably the most mysterious of all the phenomena discovered by physics.

Some striking features of quantum physics, explained below, are prerequisites.

Classical physics considers first of all closed (autonomous) physical systems. For quantum physics, systems open to external influence are of great importance.

Measurement and influence

In classical physics an ideal measurement exerts no influence on the object. It only reveals some properties of the object to the experimenter. The experimenter is able to choose an observable (a variable to be measured), or to measure all possible observables at once, and still, the object may be treated as a closed system.

Quantum physics is strikingly different. The influence of a measurement on the object is almost inevitable. If a macroscopic measuring device together with some environment is treated as a part of the quantum system (the object), and the experimenter only observes the reading of the device, then in some sense the experimenter does not influence the object. This is a subtle point related to quantum decoherence. Typically, macroscopic devices are not included into the quantum system, which implies that every measurement inevitably exerts a substantial influence on the object.

In general, two measuring devices cannot be applied simultaneously to the same object. Thus, in general, two observables are incompatible. For example, the coordinate q_x and the momentum p_x of a particle are incompatible (but q_x and p_y are compatible). The experimenter may choose one of the two observables, coordinate or momentum, and measure it, thus exerting a substantial influence on the other observable.

Local causality and influence

Local causality negates action on a distance. Basically it states that if two objects A, B are far apart in space then any external influence on A has no direct influence on B.

A strict relativistic interpretation states that a signal cannot propagate faster than light. More exactly, let A, B be two domains in space-time. (For example, A may be a given space ship during a given one-second time interval, according to its local clock, and B another space ship, 1,000,000 km apart, during its time interval.) Assume that a light ray emitted from A cannot reach B. (For example, because it can travel only 300,000 km during the given second.) Then any external influence exerted within A is of no consequence within B. (For example, a sudden explosion on the first space ship during its time interval cannot cause anxiety on the second space ship before the end of its time interval.)

Local causality does not contradict the evident existence of objects extended in space (solid bodies, sea waves and many others). For example, the hull of a space ship being a single solid body, it may seem that its parts move in ideal, non-delayed coordination; but this is an illusion. If one part was hit by a meteorite 30 nanoseconds before, this fact cannot have yet any consequence for another part 20 m apart.

An extended object is a manifestation of correlations (rather than nonlocality). Slowly propagating signals (for example, newspapers delivered by surface mail) routinely create strong correlations between remote objects, possibly not interacting with each other.