What I’m about to share may let down many children and even some adults: real magic doesn’t exist. Nobody is making things vanish and reappear, nor passing objects through walls. It’s all sleight of hand and optical illusions. However, there is a realm that feels like true magic—where everyday physics and reality seem utterly defied. Welcome to the quantum world.
In the quantum world, behavior defies our understanding. Objects seem to pass through walls and pop in and out of existence. If we could cast this behavior onto the macro scale, seeing everyday items like tables and tennis balls act as electrons and atoms do, it would be mind-blowing.
But here’s an intriguing secret: the quantum world operates under the same physical laws as our everyday world. We just can’t see the peculiar behavior at our scale. Why is that?
Firstly, consider “superposition,” where a quantum object can exist in multiple states simultaneously until measured. This concept stems from the Schrödinger equation, containing a term known as the wave function, describing the object’s various properties like position and momentum. Once a measurement occurs, properties lock into a specific state. Measurement here isn’t necessarily done by a human; any interaction counts as a measurement.
For instance, imagine you’re alone in a classroom. When another student enters, you suddenly appear in all seats at once, and only when the student interacts with a chair do you appear in just one. This illustrates quantum superposition perfectly.
Next is Quantum tunneling. It’s akin to playing squash, where sometimes the ball inexplicably passes through the wall to the adjacent court. There’s no hole in the wall; Quantum objects like electrons can pass energy barriers due to their wave functions extending through spacetime.
Another fascinating aspect is the uncertainty principle by Werner Heisenberg. It limits how precisely we can know specific pairs of properties of a particle, like position and momentum. The clearer we know one, the less we can know the other. Imagine waving a rope: if wavy enough, pinpointing its position is tough, but the wave pattern is clear. Conversely, a single wave makes position obvious but not its wavelength.
Imagine if every squash ball you hit appeared to come from the wall rather than the machine. Balls in quantum superposition only localize when hitting the wall. With two slits in the wall, balls re-emerge in the adjacent court, creating an interference pattern as waves would.
Why don’t we observe these quantum behaviors in our daily life? Quantum mechanics applies to everything, including squash balls, but its effects are too minute to detect in our macroscopic world.
Subatomic particles act like waves, but large objects are comprised of countless atoms, each behaving randomly and creating incoherence. To make a large object like a squash ball act like a quantum object, it would need perfect coherence among all its atoms, which is near impossible.
While coherence is unattainable for large objects like squash balls, it has been achieved in some molecules and macro objects like superconductors and superfluids under specific conditions. For instance, superconductors at low temperatures show unified quantum behavior over large scales.
To sum up, quantum mechanics is pervasive. If we could scale down or amplify its effects, our world would look entirely different, revealing the true magical core of our universe.