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One Qubit can be represented on the Bloch sphere. How would multiple entangled Qubits (say 2 or 3) be represented? Classically, one would think that if one Qubit is represented on a Bloch sphere, 2 Qubits would be represented on 2 Bloch spheres, but I'm pretty sure it doesn't work this way.
I believe it takes 2 complex numbers to represent one Qubit, ##\alpha_0 |0> + \alpha_1 |1>##, where the ##\alpha_a## are complex numbers, and this winds up maps to the 2-sphere because SU(2) is a double cover of SO(3). It takes 4 complex numbers to represent 2 (entangled) Qubits, and 8 complex numbers to represent 3 (entangled) Qubits, i.e. for the last case, ##\alpha_0 |000> + \alpha_1 |001> + ... \alpha_7 |111>##. So it I don't think 3 Bloch spheres can possibly represent 3 entangled Qubits, as it doesn't seem like there are enough degrees of freedom. Is there a reasonably simple geometric figure of higher dimension that can? Or some other way to represent or visualize 3 Qubits?
I believe it takes 2 complex numbers to represent one Qubit, ##\alpha_0 |0> + \alpha_1 |1>##, where the ##\alpha_a## are complex numbers, and this winds up maps to the 2-sphere because SU(2) is a double cover of SO(3). It takes 4 complex numbers to represent 2 (entangled) Qubits, and 8 complex numbers to represent 3 (entangled) Qubits, i.e. for the last case, ##\alpha_0 |000> + \alpha_1 |001> + ... \alpha_7 |111>##. So it I don't think 3 Bloch spheres can possibly represent 3 entangled Qubits, as it doesn't seem like there are enough degrees of freedom. Is there a reasonably simple geometric figure of higher dimension that can? Or some other way to represent or visualize 3 Qubits?