mathematical physics Mathematical physics is the development of mathematics, mathematical methods for application to problems in physics. The ''Journal of Mathematical Physics'' defines the field as "the application of mathematics to problems in physics and the de ...

, some approaches to

quantum field theory In theoretical physics, quantum field theory (QFT) is a theoretical framework that combines Field theory (physics), field theory and the principle of relativity with ideas behind quantum mechanics. QFT is used in particle physics to construct phy ...

are more popular than others. For historical reasons, the

Schrödinger representation In mathematics, the oscillator representation is a projective unitary representation of the symplectic group, first investigated by Irving Segal, David Shale, and André Weil. A natural extension of the representation leads to a semigroup of contra ...

is less favored than

Fock space The Fock space is an algebraic construction used in quantum mechanics to construct the quantum states space of a variable or unknown number of identical particles from a single particle Hilbert space . It is named after V. A. Fock who first intro ...

methods. In the early days of

, maintaining symmetries such as

Lorentz invariance In a relativistic theory of physics, a Lorentz scalar is a scalar expression whose value is invariant under any Lorentz transformation. A Lorentz scalar may be generated from, e.g., the scalar product of vectors, or by contracting tensors. While ...

, displaying them manifestly, and proving renormalisation were of paramount importance. The Schrödinger representation is not manifestly Lorentz invariant and its renormalisability was only shown as recently as the 1980s by Kurt Symanzik (1981). The Schrödinger functional is, in its most basic form, the

time translation Time-translation symmetry or temporal translation symmetry (TTS) is a mathematical transformation in physics that moves the times of events through a common interval. Time-translation symmetry is the law that the laws of physics are unchanged ...

generator of state wavefunctionals. In layman's terms, it defines how a system of

quantum In physics, a quantum (: quanta) is the minimum amount of any physical entity (physical property) involved in an interaction. The fundamental notion that a property can be "quantized" is referred to as "the hypothesis of quantization". This me ...

particles evolves through time and what the subsequent systems look like.

Background

Quantum mechanics is defined over the spatial coordinates

\mathbf

upon which the Galilean group acts, and the corresponding operators act on its state as

\hat\psi(\mathbf)= \mathbf\psi(\mathbf)

. The state is characterized by a

wave function In quantum physics, a wave function (or wavefunction) is a mathematical description of the quantum state of an isolated quantum system. The most common symbols for a wave function are the Greek letters and (lower-case and capital psi (letter) ...

\psi(\mathbf)=\langle\mathbf, \psi\rangle

obtained by projecting it onto the coordinate eigenstates defined by

\hat\left, \mathbf\right\rangle = \mathbf\left, \mathbf\right\rangle

. These eigenstates are not stationary.

Time evolution Time evolution is the change of state brought about by the passage of time, applicable to systems with internal state (also called ''stateful systems''). In this formulation, ''time'' is not required to be a continuous parameter, but may be discr ...

is generated by the Hamiltonian, yielding the Schrödinger equation

i\partial_0\left, \psi(t)\right\rangle = \hat\left, \psi(t)\right\rangle

. However, in

, the coordinate is the field operator

\hat_\mathbf=\hat(\mathbf)

, which acts on the state's wave functional as :

\hat(\mathbf) \Psi\left phi(\cdot)\right = \operatorname\phi\left(\mathbf\right) \Psi\left phi(\cdot)\right,

where "" indicates an unbound spatial argument. This wave functional :

= \left\langle\phi(\cdot), \Psi\right\rangle

is obtained by means of the field eigenstates :

\hat(\mathbf) \left, \Phi(\cdot)\right\rangle = \Phi(\mathbf) \left, \Phi(\cdot)\right\rangle ,

which are indexed by unapplied "classical field" configurations

\Phi(\cdot)

. These eigenstates, like the position eigenstates above, are not stationary. Time evolution is generated by the

Hamiltonian Hamiltonian may refer to: * Hamiltonian mechanics, a function that represents the total energy of a system * Hamiltonian (quantum mechanics), an operator corresponding to the total energy of that system ** Dyall Hamiltonian, a modified Hamiltonian ...

, yielding the Schrödinger equation, :

i\partial_0\left, \Psi(t)\right\rangle = \hat\left, \Psi(t)\right\rangle .

Thus the state in quantum field theory is conceptually a functional superposition of field configurations.

Example: scalar field

In the

of (as example) a quantum

scalar field In mathematics and physics, a scalar field is a function associating a single number to each point in a region of space – possibly physical space. The scalar may either be a pure mathematical number ( dimensionless) or a scalar physical ...

\hat(x)

, in complete analogy with the one-particle

quantum harmonic oscillator The quantum harmonic oscillator is the quantum-mechanical analog of the classical harmonic oscillator. Because an arbitrary smooth potential can usually be approximated as a harmonic potential at the vicinity of a stable equilibrium point, ...

, the eigenstate of this quantum field with the "classical field"

\phi(x)

( c-number) as its eigenvalue, :

\hat(x)\left, \phi\right\rangle =\phi\left(x\right)\left, \phi\right\rangle

is (Schwartz, 2013) :

\left, \phi\right\rangle \propto e^\left, 0\right\rangle

where

\hat_\left(x\right)

is the part of

\hat\left( x\right)

that ''only includes creation operators''

a^\dagger_k

. For the oscillator, this corresponds to the representation change/map to the , ''x''⟩ state from Fock states. For a time-independent Hamiltonian , the Schrödinger functional is defined as :

\langle\,\phi_2\,, e^, \,\phi_1\,\rangle.

In the

, this functional generates

s of state wave functionals, through :

\Psi phi_2,t_2 = \int\!\mathcal\phi_1\,\,\mathcal phi_2,t_2;\phi_1,t_1 Psi phi_1,t_1 .

States

The normalized,

vacuum state In quantum field theory, the quantum vacuum state (also called the quantum vacuum or vacuum state) is the quantum state with the lowest possible energy. Generally, it contains no physical particles. However, the quantum vacuum is not a simple ...

, free field wave-functional is the Gaussian :

\Psi_0

phi Phi ( ; uppercase Φ, lowercase φ or ϕ; ''pheî'' ; Modern Greek: ''fi'' ) is the twenty-first letter of the Greek alphabet. In Archaic and Classical Greek (c. 9th to 4th century BC), it represented an aspirated voiceless bilabial plos ...

= \det^ \left(\frac\right)\; e^ = \det^\left(\frac\right)\; e^, where the covariance ''K'' is :

K(\vec,\vec) = \int \frac \omega_\,e^.

This is analogous to (the Fourier transform of) the product of each k-mode's ground state in the

continuum limit In mathematical physics and mathematics, the continuum limit or scaling limit of a lattice model characterizes its behaviour in the limit as the lattice spacing goes to zero. It is often useful to use lattice models to approximate real-world pr ...

, roughly (Hatfield 1992) :

= \lim_\;\prod_ \left(\frac\right)^ e^ \to \left(\prod_ \left(\frac\right)^\right) e^.

Each k-mode enters as an independent

. One-particle states are obtained by exciting a single mode, and have the form, :

\Psi

\propto \int d\vec \int d\vec\, \phi(\vec) K(\vec,\vec) f(\vec) \Psi_0

= \phi\cdot K\cdot f\, e^ . For example, putting an excitation in

\vec_1

yields (Hatfield 1992) :

\Psi_1 tilde\phi = \left(\frac\right)^ \tilde\phi(\vec_1) \Psi_0 tilde\phi /math>
: \Psi_1

= \left(\frac\right)^ \int d^3 y\,e^\phi(\vec y)\Psi_0

. (The factor of

(2\pi)^

stems from Hatfield's setting

\Delta k = 1

Example: fermion field

For clarity, we consider a massless Weyl–Majorana field

\hat\psi(x)

in 2D space in SO⁺(1, 1), but this solution generalizes to any massive

Dirac Paul Adrien Maurice Dirac ( ; 8 August 1902 – 20 October 1984) was an English mathematician and theoretical physicist who is considered to be one of the founders of quantum mechanics. Dirac laid the foundations for both quantum electrodyna ...

bispinor In physics, and specifically in quantum field theory, a bispinor is a mathematical construction that is used to describe some of the fundamental particles of nature, including quarks and electrons. It is a specific embodiment of a spinor, specifi ...

in SO⁺(1, 3). The configuration space consists of functionals

\Psi /math> of anti-commuting Grassmann-valued fields .  The effect of \hat\psi(x) is

: \hat\psi(x), \Psi\rangle = \frac\left(u(x) + \frac\right) , \Psi\rangle .

References

* Brian Hatfield, ''Quantum Field Theory of Point Particles and Strings''. Addison Wesley Longman, 1992. See Chapter 10 "Free Fields in the Schrödinger Representation". * I.V. Kanatchikov, "Precanonical Quantization and the Schrödinger Wave Functional." ''Phys. Lett. A'' 283 (2001) 25–36. Eprin
arXiv:hep-th/0012084
16 pages. * R. Jackiw, "Schrödinger Picture for Boson and Fermion Quantum Field Theories." In ''Mathematical Quantum Field Theory and Related Topics: Proceedings of the 1987 Montréal Conference Held September 1–5, 1987'' (eds. J.S. Feldman and L.M. Rosen, American Mathematical Society 1988). * H. Reinhardt, C. Feuchter, "On the Yang-Mills wave functional in Coulomb gauge." ''Phys. Rev. D'' 71 (2005) 105002. Eprin
arXiv:hep-th/0408237
9 pages. * D.V. Long, G.M. Shore, "The Schrödinger Wave Functional and Vacuum States in Curved Spacetime." ''Nucl.Phys. B'' 530 (1998) 247–278. Eprin
arXiv:hep-th/9605004
41 pages. * Kurt Symanzik, "Schrödinger representation and Casimir effect in renormalizable quantum field theory". ''Nucl. Phys.B'' 190 (1981) 1–44
doi:10.1016/0550-3213(81)90482-X
* K. Symanzik, "Schrödinger Representation in Renormalizable Quantum Field Theory". Chapter in ''Structural Elements in Particle Physics and Statistical Mechanics'', NATO Advanced Study Institutes Series 82 (1983) pp 287–299
doi:10.1007/978-1-4613-3509-2_20
* Martin Lüscher, Rajamani Narayanan, Peter Weisz, Ulli Wolff, "The Schrödinger Functional - a Renormalizable Probe for Non-Abelian Gauge Theories". ''Nucl.Phys.B'' 384 (1992) 168–228
doi:10.1016/0550-3213(92)90466-O
Eprin
arXiv:hep-lat/9207009
* Matthew Schwartz (2013). ''Quantum Field Theory and the Standard Model'', Cambridge University Press, Ch.14. {{DEFAULTSORT:Schrodinger Functional Quantum field theory Functional