Quantum Entanglement & Spooky Action at a Distance

Veritasium

12 Jan 201509:15

Summary

TLDRThis script delves into the quantum mechanics concept of 'spooky action at a distance,' where particles instantaneously affect each other regardless of distance. It explores the property of spin in fundamental particles and how measuring one affects its entangled partner. The script explains Einstein's discomfort with this phenomenon, suggesting hidden variables, and contrasts it with John Bell's experiments that support the non-locality of quantum mechanics. The discussion concludes with the consensus that, while entanglement is mysterious, it does not allow for faster-than-light communication, aligning with Einstein's relativity.

Takeaways

🤔 Albert Einstein was skeptical of quantum mechanics and its implications for 'spooky action at a distance', which seemed to allow for faster-than-light communication.
🌌 The concept of 'spooky action at a distance' is rooted in quantum entanglement, where the state of one particle instantaneously influences another, regardless of distance.
🔄 Quantum particles possess a property called 'spin', which is a form of angular momentum and orientation in space, and can be measured in one of two outcomes: 'spin up' or 'spin down'.
🎯 Measuring the spin of a particle in a certain direction changes the particle's spin, and the outcome is probabilistic, depending on the angle of measurement.
🤝 When two entangled particles are created, their spins are not predefined but are correlated such that measuring one immediately determines the spin of the other.
🚫 Einstein proposed that particles have 'hidden variables' that determine their spin in all possible measurement directions, which would allow for no faster-than-light communication.
🔬 John Bell developed an experiment to test whether particles have hidden information, which involves measuring entangled particles in different directions and comparing the results.
📊 The Bell experiment showed that the outcomes of spin measurements do not align with the hidden variable theory, suggesting that particles do not have predefined spins.
🌐 Quantum mechanics explains the results of the Bell experiment by stating that entangled particles do not have definite spins until measured, leading to a 50% chance of matching or differing results.
✉️ Despite the 'spooky' nature of entanglement, it does not enable faster-than-light communication, as the outcomes are random and only appear correlated upon comparison.

Q & A

What was Albert Einstein's view on quantum mechanics in the 1930s?
-Albert Einstein was upset with quantum mechanics, particularly the concept of 'spooky action at a distance' which suggested that events could affect each other instantaneously across vast distances, seemingly violating the principles of his theory of relativity.
What is meant by 'spooky action at a distance' in quantum mechanics?
-'Spooky action at a distance' refers to the phenomenon where two entangled particles can affect each other's state instantaneously, no matter how far apart they are, which Einstein found absurd and at odds with the speed of light limit set by relativity.
Why is the concept of spin important in understanding quantum entanglement?
-Spin is a fundamental property of particles that describes their angular momentum and orientation in space. In quantum entanglement, the spin states of entangled particles are correlated in such a way that the measurement of one immediately determines the state of the other, regardless of the distance between them.
How does measuring the spin of a particle affect its state?
-Measuring the spin of a particle forces it to take on a definite spin state along the direction of measurement. Prior to measurement, the particle is in a superposition of states, but upon measurement, it 'collapses' to either spin up or spin down along the chosen axis.
What is entanglement in quantum mechanics, and how does it relate to the conservation of angular momentum?
-Entanglement is a quantum phenomenon where the states of two or more particles become interdependent such that the state of one particle cannot be described independently of the others. In the context of angular momentum, if one particle is measured to have spin up, its entangled partner must have spin down to conserve total angular momentum.
Why can't particles have a well-defined spin state before measurement according to quantum mechanics?
-According to quantum mechanics, particles do not have a well-defined spin state before measurement because such a definition would imply predetermined outcomes for all possible measurements, which contradicts the probabilistic nature of quantum states and the observed correlations in entangled systems.
What was Einstein's alternative explanation to the phenomenon of entanglement?
-Einstein proposed that entangled particles contain 'hidden information' or 'hidden variables' that determine their spin states in all possible measurement directions, which are only revealed upon measurement. This idea suggests that no information is transmitted faster than light, as the states are predetermined.
Who was John Bell and what was his contribution to the debate on quantum mechanics?
-John Bell was a physicist who proposed Bell's theorem, which provided a way to test whether quantum particles contain hidden information as Einstein suggested or not. Bell's inequality experiments have shown that the predictions of quantum mechanics are correct, suggesting that particles do not have predetermined hidden variables.
How do the results of Bell's inequality experiments challenge the idea of hidden variables in quantum particles?
-Bell's inequality experiments have shown that the correlations between entangled particles are stronger than what could be explained by hidden variables alone. The results are consistent with quantum mechanics, which predicts that particles do not have predetermined states until measured, thus challenging the idea of hidden variables.
Why can't entangled particles be used to communicate faster than light despite their instantaneous correlations?
-While entangled particles exhibit instantaneous correlations, the outcomes of individual measurements are random and cannot be controlled. This randomness means that no information can be reliably sent from one particle to another, thus not allowing for faster-than-light communication and not violating the theory of relativity.
What is the significance of the 50/50 result in the context of Bell's inequality experiments?
-The 50/50 result in Bell's inequality experiments indicates that the outcomes of measurements on entangled particles are not predetermined and do not conform to the expectations of local hidden variable theories. This result supports the quantum mechanical view that particles are in a superposition of states until measured.