The Many Hidden Worlds of Quantum Mechanics — Season 1, Episode 21: The Quantum Emergence of Time

Episode synopsis

As space might be an emergent property of quantum entanglement, could the same be true of time? Divide a wave function into subsystems and watch how the rest of the universe becomes entangled in a manner that can be interpreted as time passing. Along the way, learn the ideas behind the Wheeler-DeWitt equation, which helped define the "problem of time."

About The Many Hidden Worlds of Quantum Mechanics

One universe is not enough. Learn about the Many-Worlds Interpretation of quantum mechanics in this exciting course taught by a renowned expert, Sean Carroll.

More episodes from Season 1

• E1Why Suppose There's More Than One World?
• E2The Classical Physics World That Never Was
• E3Quantum Worlds Start With Waves and Particles
• E4A Wave Function to Describe Particles
• E5Copenhagen Says the Wave Function Collapses
• E6Is the Wave Function Real?
• E7Uncertainty in Action With Spin and Qubits
• E8Quantum Entanglement and Action at a Distance
• E9Entanglement Leads to Many Worlds
• E10Decoherence Explains Branching Worlds
• E11How Entanglement Powers Quantum Computers
• E12Too Many Worlds! Five Objections Answered