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Love*Physics
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Why it doesn't look the same if one turns spin ½ particles through just one revolution but it will be the same if we turn them through two complete revolutions?
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Love*Physics said:Why it doesn't look the same if one turns spin ½ particles through just one revolution but it will be the same if we turn them through two complete revolutions?
olgranpappy said:it *does* look the same.
GDogg said:I suppose that you're interepreting a revolution for spins as a rotation by 4pi?
He's asking the reason why a particle's spin doesn't remain invariant when you rotate it by 2pi using the corresponding rotation operator.
The easy answer is that spin doesn't live in normal 3D space so it doesn't transform with the usual rotation matrices from classical mechanics. Classical objects rotate using a representation of the group SO(3), whereas spin vectors rotate with a representation of the group SU(2).
Fredrik said:There's no way to really draw a picture of this. 2 complex dimensions are equivalent to 4 real dimensions and we can't draw more than 3. Roger Penrose suggests the following picture, but I don't think it's helpful at all: Put one end of a long belt on the table, under something heavy, and put the other end between two pages in a book. Now rotate this book by 4 pi around the axis defined by the belt. Without rotating the book any further, you can "undo" the 4 pi rotation by looping the belt around the book. This doesn't work with a 2 pi rotation.
mlcen said:Thank you very much! It is a good explanation.
GDogg said:I suppose that you're interepreting a revolution for spins as a rotation by 4pi?
olgranpappy said:no. i meant that it *does* look the same in that the state
[tex]
-|\psi\rangle
[/tex]
is physically the same as the ket
[tex]
|\psi\rangle
[/tex]
or any other ket which differs only by an overall phase.
Since those states are physically the same, then one is justified in saying they "look" the same. Right? What do you mean by "look"?
DeShark said:I read also that a waitress with a tray works nicely. If she rotates the tray once, her arm is twisted. To regain the original state, she has to rotate the tray by 720 degrees. I think you have to try it to see what I mean. I believe it was Feynman who gave me this picture, to give credit where it's due.
mlcen said:Thank you very much! This is a perfect explanation.
You are humorous really. Good.olgranpappy said:It is cute, but not perfect. Like a recently deceased kitten. Cheers.
mlcen said:Thank you very much! It is a good explanation.
Thank you! It is a visualized explanation. But I think it is similar to a picture of Berry phase, isn't it?StatusX said:It's nice to see a 4pi rotation is significant somehow, but this doesn't really make it clear what this has to do with spin 1/2 particles. What part of an electron is analagous to the belt?
Here's one way to understand it. Let the belt represent the path of the electron through spacetime. The electron may twist and turn as it travels, but let's say that at certain points, it has the same orientation it started with. When this happens, the electron must be in a state related to the original one by some constant factor.
What can this constant be? Well, we need to assign it in such a way that the state of the electron varies continuously along its path, ie, no sudden jumps. Let's say the electron has done two complete rotations since it started. Can the constant we assign at this point be something besides one?
The belt trick says no. To see why, let's suppose we could make it something else, say A. Then we've assigned a state to the electron at every point along the path in such a way that it starts at some state [itex]|\psi>[/itex] and ends at some state [itex]A|\psi>[/itex]. Now, using the belt trick, we can continuously deform this path to one where the electron doesn't rotate at all. But we're holding the ends of the belt fixed, so it still has to start at [itex]|\psi>[/itex] and end at [itex]A|\psi>[/itex]. But this should be true no matter how short the path is, and when we take the path to be very small, this means the state must change discontinuously, unless A=1. On the other hand, a single rotation cannot be so deformed, so the constant doesn't have to be 1. However, it's restricted by the fact that doing this twice must return you to the original state, so it must be either 1 or -1. For an electron, it turns out the constant is -1.
Here's a more technical explanation. The belt is supposed to represent is a path through SO(3), the group of rotations in 3 dimensions. Namely, each point along the belt corresponds to a rotation: the rotation that brings that slice of the belt into its current orientation. So we have a one parameter family of elements in SO(3), ie, a path in SO(3). Then by deforming the belt while holding its two ends fixed, we get a deformation of the path, ie, a homotopy of paths. The fact that a twice twisted belt can be deformed to a straight belt (while a once twisted belt can not) is then just the demonstration that a path in SO(3) corresponding to a 4pi rotation is homotopic to the constant path (while a 2pi rotation is not), ie, that the fundamental group of SO(3) is Z2. Thus the rotation group is not simply connected, and so it has representations that are not single valued. For one reason or another, nature chooses to use one of these representations for certain particles, such as the electron.
Fredrik said:There's no way to really draw a picture of this. 2 complex dimensions are equivalent to 4 real dimensions and we can't draw more than 3. Roger Penrose suggests the following picture, but I don't think it's helpful at all: Put one end of a long belt on the table, under something heavy, and put the other end between two pages in a book. Now rotate this book by 4 pi around the axis defined by the belt. Without rotating the book any further, you can "undo" the 4 pi rotation by looping the belt around the book. This doesn't work with a 2 pi rotation.
Spin ½ particles are subatomic particles, such as electrons and protons, that have a quantum mechanical property called spin. This spin is intrinsic to the particle and can take on the values of either +½ or -½.
Spin in spin ½ particles is measured in units of h/2π, where h is Planck's constant. This measurement is known as the spin quantum number and determines the orientation of the particle's spin in relation to an external magnetic field.
Spin ½ particles are important in the field of quantum mechanics because they behave differently from classical particles. They can have both wave-like and particle-like properties and exhibit quantum entanglement, making them crucial for understanding the behavior of matter at the atomic and subatomic level.
No, spin ½ particles cannot change their spin state. The spin quantum number remains constant for a given particle. However, when measured in different directions, the spin can appear to change, as it is a probabilistic measurement.
This concept refers to how spin ½ particles behave differently from classical particles when rotated. In classical mechanics, rotating an object twice will bring it back to its original position. However, in quantum mechanics, rotating a spin ½ particle twice can result in a different state, as it can have a spin of either +½ or -½. This phenomenon is known as spin statistics and has implications in various fields, including quantum computing and particle physics.