Confidence region

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In theoretical physics, the label superpotential denotes a concept used in supersymmetric quantum mechanics.

Example of superpotentiality

Consider the example of a one dimensional, non-relativistic particle with a 2D (i.e. two state) internal degree of freedom called "spin". (It does not really spin because "real" spin applies only to particles in three-dimensional space.) Let b signify an operator which transforms a "spin up" particle into a "spin down" particle and its Hermitian adjoint (b) transforming a spin down particle into a spin up particle normalized such that the anticommutator (b,b) equals 1. And of course, b2 equals 0. Let p represent the momentum of the particle and x represent its position with [x,p]=i (let's use natural units where =1). Let W (the superpotential) represent an arbitrary differentiable function of x and let the supersymmetric operators represent:

Q1=12[(piW)b+(p+iW)b]
Q2=i2[(piW)b(p+iW)b]

Note that Q1 and Q2 seem self-adjoint. Let the Hamiltonian

H={Q1,Q1}={Q2,Q2}=p22+W22+W2(bbbb)

where W' signifies the derivative of W. Also note that {Q1,Q2}=0. This shows nothing other than N=2 supersymmetry.

Most call the spin down state "bosonic" and the spin up state "fermionic". This exists only in analogy to quantum field theory and should not be taken literally. Then, Q1 and Q2 maps "bosonic" states into "fermionic" states and vice versa. Restricting to the bosonic or fermionic sectors gives two partner potentials determined by

H=p22+W22±W2

Superpotential in dimension 4

In the theory supersymmetry with four dimensions, which might have some connection to the nature, physicists insist a scalar field as the lowest component of a chiral superfield, which tends to automatically contain complexities. You may identify the complex conjugate of a chiral superfield as an anti-chiral superfield.

To obtain the action from a set of superfields, two choices may occur

  • Integrate a superfield on the whole superspace spanned by x0,1,2,3 and

θ,θ¯

or

  • Integrate a chiral superfield on the chiral half of a superspace, spanned by x0,1,2,3

and θ, not on θ¯.

Thus, when given a set of chiral superfields and an arbitrary holomorphic function of them, W, a term in the Lagrangian constructed by which invariant under supersymmetry, W cannot depend on the complex conjugates. The function W may be classified as the superpotential. The fact that W tends to have holomorphic properties in the chiral superfields shows the source of the tractability of supersymmetric theories. Indeed, we know W to receive no perturbative corrections, which celebrates the perturbative non-renormalization theorem. The non-perturbative processes may correct it, e.g., by instantons.

References