Nonlinear Scalar Field Theory
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In theoretical physics, scalar field theory can refer to a relativistically invariant classical or quantum theory of
scalar field In mathematics and physics, a scalar field is a function (mathematics), function associating a single number to every point (geometry), point in a space (mathematics), space – possibly physical space. The scalar may either be a pure Scalar ( ...
s. A scalar field is invariant under any Lorentz transformation. The only fundamental scalar quantum field that has been observed in nature is the Higgs field. However, scalar quantum fields feature in the
effective field theory In physics, an effective field theory is a type of approximation, or effective theory, for an underlying physical theory, such as a quantum field theory or a statistical mechanics model. An effective field theory includes the appropriate degrees ...
descriptions of many physical phenomena. An example is the pion, which is actually a pseudoscalar. Since they do not involve
polarization Polarization or polarisation may refer to: Mathematics *Polarization of an Abelian variety, in the mathematics of complex manifolds *Polarization of an algebraic form, a technique for expressing a homogeneous polynomial in a simpler fashion by ...
complications, scalar fields are often the easiest to appreciate second quantization through. For this reason, scalar field theories are often used for purposes of introduction of novel concepts and techniques. The signature of the metric employed below is .


Classical scalar field theory

A general reference for this section is Ramond, Pierre (2001-12-21). Field Theory: A Modern Primer (Second Edition). USA: Westview Press. , Ch 1.


Linear (free) theory

The most basic scalar field theory is the linear theory. Through the
Fourier decomposition A Fourier series () is a summation of harmonically related sinusoidal functions, also known as components or harmonics. The result of the summation is a periodic function whose functional form is determined by the choices of cycle length (or ''p ...
of the fields, it represents the
normal modes A normal mode of a dynamical system is a pattern of motion in which all parts of the system move sinusoidally with the same frequency and with a fixed phase relation. The free motion described by the normal modes takes place at fixed frequencies. ...
of an infinity of coupled oscillators where the continuum limit of the oscillator index ''i'' is now denoted by . The action for the free relativistic scalar field theory is then :\begin \mathcal &= \int \mathrm^x \mathrmt \mathcal \\ &= \int \mathrm^x \mathrmt \left frac\eta^\partial_\mu\phi\partial_\nu\phi - \frac m^2\phi^2\right\\ pt &= \int \mathrm^x \mathrmt \left frac(\partial_t\phi)^2 - \frac\delta^\partial_i\phi \partial_j\phi -\frac m^2\phi^2\right \end where \mathcal is known as a Lagrangian density; for the three spatial coordinates; is the Kronecker delta function; and for the -th coordinate . This is an example of a quadratic action, since each of the terms is quadratic in the field, . The term proportional to is sometimes known as a mass term, due to its subsequent interpretation, in the quantized version of this theory, in terms of particle mass. The equation of motion for this theory is obtained by extremizing the action above. It takes the following form, linear in , :\eta^\partial_\mu\partial_\nu\phi+m^2\phi=\partial^2_t\phi-\nabla^2\phi+m^2\phi=0 ~, where ∇2 is the
Laplace operator In mathematics, the Laplace operator or Laplacian is a differential operator given by the divergence of the gradient of a scalar function on Euclidean space. It is usually denoted by the symbols \nabla\cdot\nabla, \nabla^2 (where \nabla is the ...
. This is the Klein–Gordon equation, with the interpretation as a classical field equation, rather than as a quantum-mechanical wave equation.


Nonlinear (interacting) theory

The most common generalization of the linear theory above is to add a scalar potential to the Lagrangian, where typically, in addition to a mass term, ''V'' is a polynomial in . Such a theory is sometimes said to be interacting, because the Euler–Lagrange equation is now nonlinear, implying a self-interaction. The action for the most general such theory is :\begin \mathcal &= \int \mathrm^x \, \mathrmt \mathcal \\ pt &= \int \mathrm^x \mathrmt \left frac\eta^\partial_\mu\phi\partial_\nu\phi - V(\phi) \right\\ pt &= \int \mathrm^x \, \mathrmt \left \frac(\partial_t\phi)^2 - \frac\delta^\partial_i\phi\partial_j\phi - \fracm^2\phi^2 - \sum_^\infty \frac g_n\phi^n \right\end The ''n''! factors in the expansion are introduced because they are useful in the Feynman diagram expansion of the quantum theory, as described below. The corresponding Euler–Lagrange equation of motion is now :\eta^ \partial_\mu \partial_\nu\phi + V'(\phi) = \partial^2_t \phi - \nabla^2 \phi + V'(\phi) = 0.


Dimensional analysis and scaling

Physical quantities in these scalar field theories may have dimensions of length, time or mass, or some combination of the three. However, in a relativistic theory, any quantity , with dimensions of time, can be readily converted into a ''length'', , by using the velocity of light, . Similarly, any length is equivalent to an inverse mass, , using Planck's constant, . In natural units, one thinks of a time as a length, or either time or length as an inverse mass. In short, one can think of the dimensions of any physical quantity as defined in terms of ''just one'' independent dimension, rather than in terms of all three. This is most often termed the
mass dimension Mass is an intrinsic property of a body. It was traditionally believed to be related to the quantity of matter in a physical body, until the discovery of the atom and particle physics. It was found that different atoms and different elementar ...
of the quantity. Knowing the dimensions of each quantity, allows one to ''uniquely restore'' conventional dimensions from a natural units expression in terms of this mass dimension, by simply reinserting the requisite powers of and required for dimensional consistency. One conceivable objection is that this theory is classical, and therefore it is not obvious how Planck's constant should be a part of the theory at all. If desired, one could indeed recast the theory without mass dimensions at all: However, this would be at the expense of slightly obscuring the connection with the quantum scalar field. Given that one has dimensions of mass, Planck's constant is thought of here as an essentially ''arbitrary fixed reference quantity of action'' (not necessarily connected to quantization), hence with dimensions appropriate to convert between mass and inverse length.


Scaling dimension

The
classical scaling dimension In theoretical physics, the scaling dimension, or simply dimension, of a local operator in a quantum field theory characterizes the rescaling properties of the operator under spacetime dilations x\to \lambda x. If the quantum field theory is scale ...
, or mass dimension, , of describes the transformation of the field under a rescaling of coordinates: :x\rightarrow\lambda x :\phi\rightarrow\lambda^\phi ~. The units of action are the same as the units of , and so the action itself has zero mass dimension. This fixes the scaling dimension of the field to be :\Delta =\frac.


Scale invariance

There is a specific sense in which some scalar field theories are
scale-invariant In physics, mathematics and statistics, scale invariance is a feature of objects or laws that do not change if scales of length, energy, or other variables, are multiplied by a common factor, and thus represent a universality. The technical ter ...
. While the actions above are all constructed to have zero mass dimension, not all actions are invariant under the scaling transformation :x\rightarrow\lambda x :\phi\rightarrow\lambda^\phi ~. The reason that not all actions are invariant is that one usually thinks of the parameters ''m'' and as fixed quantities, which are not rescaled under the transformation above. The condition for a scalar field theory to be scale invariant is then quite obvious: all of the parameters appearing in the action should be dimensionless quantities. In other words, a scale invariant theory is one without any fixed length scale (or equivalently, mass scale) in the theory. For a scalar field theory with spacetime dimensions, the only dimensionless parameter satisfies = . For example, in = 4, only is classically dimensionless, and so the only classically scale-invariant scalar field theory in = 4 is the massless 4 theory. Classical scale invariance, however, normally does not imply quantum scale invariance, because of the renormalization group involved – see the discussion of the beta function below.


Conformal invariance

A transformation :x\rightarrow \tilde(x) is said to be
conformal Conformal may refer to: * Conformal (software), in ASIC Software * Conformal coating in electronics * Conformal cooling channel, in injection or blow moulding * Conformal field theory in physics, such as: ** Boundary conformal field theory ...
if the transformation satisfies :\frac\frac\eta_=\lambda^2(x)\eta_ for some function . The conformal group contains as subgroups the isometries of the metric \eta_ (the Poincaré group) and also the scaling transformations (or
dilatation Dilation (or dilatation) may refer to: Physiology or medicine * Cervical dilation, the widening of the cervix in childbirth, miscarriage etc. * Coronary dilation, or coronary reflex * Dilation and curettage, the opening of the cervix and surgic ...
s) considered above. In fact, the scale-invariant theories in the previous section are also conformally-invariant.


4 theory

Massive 4 theory illustrates a number of interesting phenomena in scalar field theory. The Lagrangian density is :\mathcal=\frac(\partial_t\phi)^2 -\frac\delta^\partial_i\phi\partial_j\phi - \fracm^2\phi^2-\frac\phi^4.


Spontaneous symmetry breaking

This Lagrangian has a ℤ₂ symmetry under the transformation . This is an example of an internal symmetry, in contrast to a space-time symmetry. If is positive, the potential :V(\phi)=\fracm^2\phi^2 +\frac\phi^4 has a single minimum, at the origin. The solution ''φ''=0 is clearly invariant under the ℤ₂ symmetry. Conversely, if is negative, then one can readily see that the potential :\, V(\phi)=\fracm^2\phi^2+\frac\phi^4\! has two minima. This is known as a ''double well potential'', and the lowest energy states (known as the vacua, in quantum field theoretical language) in such a theory are invariant under the ℤ₂ symmetry of the action (in fact it maps each of the two vacua into the other). In this case, the ℤ₂ symmetry is said to be ''
spontaneously broken Spontaneous symmetry breaking is a spontaneous process of symmetry breaking, by which a physical system in a symmetric state spontaneously ends up in an asymmetric state. In particular, it can describe systems where the equations of motion or the ...
''.


Kink solutions

The 4 theory with a negative 2 also has a kink solution, which is a canonical example of a soliton. Such a solution is of the form :\phi(\vec, t) = \pm\frac\tanh\left frac\right/math> where is one of the spatial variables ( is taken to be independent of , and the remaining spatial variables). The solution interpolates between the two different vacua of the double well potential. It is not possible to deform the kink into a constant solution without passing through a solution of infinite energy, and for this reason the kink is said to be stable. For ''D''>2 (i.e., theories with more than one spatial dimension), this solution is called a domain wall. Another well-known example of a scalar field theory with kink solutions is the
sine-Gordon The sine-Gordon equation is a nonlinear hyperbolic partial differential equation in 1 + 1 dimensions involving the d'Alembert operator and the sine of the unknown function. It was originally introduced by in the course of study of surfa ...
theory.


Complex scalar field theory

In a complex scalar field theory, the scalar field takes values in the complex numbers, rather than the real numbers. The complex scalar field represents spin-0 particles and antiparticles with charge. The action considered normally takes the form :\mathcal=\int \mathrm^x \, \mathrmt \mathcal = \int \mathrm^x \, \mathrmt \left \phi, ^2)\right/math> This has a U(1), equivalently O(2) symmetry, whose action on the space of fields rotates \phi\rightarrow e^\phi, for some real phase angle . As for the real scalar field, spontaneous symmetry breaking is found if ''m''2 is negative. This gives rise to Goldstone's Mexican hat potential which is a rotation of the double-well potential of a real scalar field by 2π radians about the ''V'' (\phi) axis. The symmetry breaking takes place in one higher dimension, i.e. the choice of vacuum breaks a continuous ''U''(1) symmetry instead of a discrete one. The two components of the scalar field are reconfigured as a massive mode and a massless Goldstone boson.


''O''(''N'') theory

One can express the complex scalar field theory in terms of two real fields, ''φ''1 = Re ''φ'' and ''φ''2 = Im ''φ'', which transform in the vector representation of the ''U''(1) = ''O''(2) internal symmetry. Although such fields transform as a vector under the ''internal symmetry'', they are still Lorentz scalars. This can be generalised to a theory of N scalar fields transforming in the vector representation of the ''O''(''N'') symmetry. The Lagrangian for an ''O''(''N'')-invariant scalar field theory is typically of the form :\mathcal=\frac\eta^\partial_\mu\phi\cdot\partial_\nu\phi -V(\phi\cdot\phi) using an appropriate ''O''(''N'')-invariant inner product. The theory can also be expressed for complex vector fields, i.e. for \phi\in\Complex^n, in which case the symmetry group is the
Lie group In mathematics, a Lie group (pronounced ) is a group that is also a differentiable manifold. A manifold is a space that locally resembles Euclidean space, whereas groups define the abstract concept of a binary operation along with the additio ...
SU(N) In mathematics, the special unitary group of degree , denoted , is the Lie group of unitary matrices with determinant 1. The more general unitary matrices may have complex determinants with absolute value 1, rather than real 1 in the specia ...
.


Gauge-field couplings

When the scalar field theory is coupled to in a gauge invariant way to the Yang–Mills action, one obtains the Ginzburg–Landau theory of superconductors. The topological solitons of that theory correspond to vortices in a superconductor; the minimum of the Mexican hat potential corresponds to the order parameter of the superconductor.


Quantum scalar field theory

A general reference for this section is Ramond, Pierre (2001-12-21). Field Theory: A Modern Primer (Second Edition). USA: Westview Press. , Ch. 4 In
quantum field theory In theoretical physics, quantum field theory (QFT) is a theoretical framework that combines classical field theory, special relativity, and quantum mechanics. QFT is used in particle physics to construct physical models of subatomic particles and ...
, the fields, and all observables constructed from them, are replaced by quantum operators on a
Hilbert space In mathematics, Hilbert spaces (named after David Hilbert) allow generalizing the methods of linear algebra and calculus from (finite-dimensional) Euclidean vector spaces to spaces that may be infinite-dimensional. Hilbert spaces arise natural ...
. This Hilbert space is built on a vacuum state, and dynamics are governed by a quantum Hamiltonian, a positive-definite operator which annihilates the vacuum. A construction of a quantum scalar field theory is detailed in the
canonical quantization In physics, canonical quantization is a procedure for quantizing a classical theory, while attempting to preserve the formal structure, such as symmetries, of the classical theory, to the greatest extent possible. Historically, this was not quite ...
article, which relies on canonical commutation relations among the fields. Essentially, the infinity of classical oscillators repackaged in the scalar field as its (decoupled) normal modes, above, are now quantized in the standard manner, so the respective quantum operator field describes an infinity of
quantum harmonic oscillator 量子調和振動子 は、 古典調和振動子 の 量子力学 類似物です。任意の滑らかな ポテンシャル は通常、安定した 平衡点 の近くで 調和ポテンシャル として近似できるため、最 ...
s acting on a respective Fock space. In brief, the basic variables are the quantum field and its canonical momentum . Both these operator-valued fields are Hermitian. At spatial points , and at equal times, their
canonical commutation relations In quantum mechanics, the canonical commutation relation is the fundamental relation between canonical conjugate quantities (quantities which are related by definition such that one is the Fourier transform of another). For example, hat x,\hat p ...
are given by :\begin \left phi\left(\vec\right), \phi\left(\vec\right)\right= \left pi\left(\vec\right), \pi\left(\vec\right)\right&= 0,\\ \left phi\left(\vec\right), \pi\left(\vec\right)\right&= i \delta\left(\vec - \vec\right), \end while the free Hamiltonian is, similarly to above, :H = \int d^3x \left pi^2 + (\nabla \phi)^2 + \phi^2\right A spatial
Fourier transform A Fourier transform (FT) is a mathematical transform that decomposes functions into frequency components, which are represented by the output of the transform as a function of frequency. Most commonly functions of time or space are transformed, ...
leads to momentum space fields :\begin \widetilde(\vec) &= \int d^3x e^\phi(\vec),\\ \widetilde(\vec) &= \int d^3x e^\pi(\vec) \end which resolve to annihilation and creation operators :\begin a(\vec) &= \left(E\widetilde(\vec) + i\widetilde(\vec)\right),\\ a^\dagger(\vec) &= \left(E\widetilde(\vec) - i\widetilde(\vec)\right), \end where E = \sqrt . These operators satisfy the commutation relations :\begin \left (\vec_1), a(\vec_2)\right= \left ^\dagger(\vec_1), a^\dagger(\vec_2)\right&= 0,\\ \left (\vec_1), a^\dagger(\vec_2)\right&= (2\pi)^3 2E \delta(\vec_1 - \vec_2). \end The state , 0\rangle annihilated by all of the operators ''a'' is identified as the ''bare vacuum'', and a particle with momentum is created by applying a^\dagger(\vec) to the vacuum. Applying all possible combinations of creation operators to the vacuum constructs the relevant
Hilbert space In mathematics, Hilbert spaces (named after David Hilbert) allow generalizing the methods of linear algebra and calculus from (finite-dimensional) Euclidean vector spaces to spaces that may be infinite-dimensional. Hilbert spaces arise natural ...
: This construction is called Fock space. The vacuum is annihilated by the Hamiltonian :H = \int \frac a^\dagger(\vec) a(\vec) , where the zero-point energy has been removed by
Wick ordering In quantum field theory a product of quantum fields, or equivalently their creation and annihilation operators, is usually said to be normal ordered (also called Wick order) when all creation operators are to the left of all annihilation operato ...
. (See
canonical quantization In physics, canonical quantization is a procedure for quantizing a classical theory, while attempting to preserve the formal structure, such as symmetries, of the classical theory, to the greatest extent possible. Historically, this was not quite ...
.) Interactions can be included by adding an interaction Hamiltonian. For a ''φ''4 theory, this corresponds to adding a Wick ordered term ''g'':''φ''4:/4! to the Hamiltonian, and integrating over ''x''. Scattering amplitudes may be calculated from this Hamiltonian in the
interaction picture In quantum mechanics, the interaction picture (also known as the Dirac picture after Paul Dirac) is an intermediate representation between the Schrödinger picture and the Heisenberg picture. Whereas in the other two pictures either the state ...
. These are constructed in perturbation theory by means of the
Dyson series In scattering theory, a part of mathematical physics, the Dyson series, formulated by Freeman Dyson, is a perturbative expansion of the time evolution operator in the interaction picture. Each term can be represented by a sum of Feynman diagrams. ...
, which gives the time-ordered products, or ''n''-particle Green's functions \langle 0, \mathcal\, 0\rangle as described in the
Dyson series In scattering theory, a part of mathematical physics, the Dyson series, formulated by Freeman Dyson, is a perturbative expansion of the time evolution operator in the interaction picture. Each term can be represented by a sum of Feynman diagrams. ...
article. The Green's functions may also be obtained from a generating function that is constructed as a solution to the Schwinger–Dyson equation.


Feynman path integral

The Feynman diagram expansion may be obtained also from the Feynman path integral formulation. The time ordered vacuum expectation values of polynomials in , known as the ''n''-particle Green's functions, are constructed by integrating over all possible fields, normalized by the vacuum expectation value with no external fields, :\langle 0, \mathcal\, 0\rangle = \frac . All of these Green's functions may be obtained by expanding the exponential in ''J''(''x'')φ(''x'') in the generating function : Z = \int \mathcal\phi e^ = Z \sum_^ \frac J(x_1) \cdots J(x_n) \langle 0, \mathcal\, 0\rangle. A Wick rotation may be applied to make time imaginary. Changing the signature to (++++) then turns the Feynman integral into a statistical mechanics partition function in Euclidean space, :Z = \int \mathcal\phi e^. Normally, this is applied to the scattering of particles with fixed momenta, in which case, a
Fourier transform A Fourier transform (FT) is a mathematical transform that decomposes functions into frequency components, which are represented by the output of the transform as a function of frequency. Most commonly functions of time or space are transformed, ...
is useful, giving instead :\tilde tilde\int \mathcal\tilde\phi e^. where \delta(x) is the
Dirac delta function In mathematics, the Dirac delta distribution ( distribution), also known as the unit impulse, is a generalized function or distribution over the real numbers, whose value is zero everywhere except at zero, and whose integral over the entire ...
. The standard trick to evaluate this functional integral is to write it as a product of exponential factors, schematically, :\tilde tilde\int \mathcal\tilde\phi \prod_p \left ^ e^ e^\right The second two exponential factors can be expanded as power series, and the combinatorics of this expansion can be represented graphically through Feynman diagrams of the Quartic interaction. The integral with g = 0 can be treated as a product of infinitely many elementary Gaussian integrals: the result may be expressed as a sum of Feynman diagrams, calculated using the following Feynman rules: * Each field (''p'') in the ''n''-point Euclidean Green's function is represented by an external line (half-edge) in the graph, and associated with momentum ''p''. * Each vertex is represented by a factor −''g''. * At a given order ''g''''k'', all diagrams with ''n'' external lines and vertices are constructed such that the momenta flowing into each vertex is zero. Each internal line is represented by a propagator 1/(''q''2 + ''m''2), where is the momentum flowing through that line. * Any unconstrained momenta are integrated over all values. * The result is divided by a symmetry factor, which is the number of ways the lines and vertices of the graph can be rearranged without changing its connectivity. * Do not include graphs containing "vacuum bubbles", connected subgraphs with no external lines. The last rule takes into account the effect of dividing by The Minkowski-space Feynman rules are similar, except that each vertex is represented by ''−ig'', while each internal line is represented by a propagator ''i''/(''q''2−''m''2+''iε''), where the term represents the small Wick rotation needed to make the Minkowski-space Gaussian integral converge.


Renormalization

The integrals over unconstrained momenta, called "loop integrals", in the Feynman graphs typically diverge. This is normally handled by renormalization, which is a procedure of adding divergent counter-terms to the Lagrangian in such a way that the diagrams constructed from the original Lagrangian and counter-terms is finite.See the previous reference, or for more detail, A renormalization scale must be introduced in the process, and the coupling constant and mass become dependent upon it. The dependence of a coupling constant on the scale is encoded by a beta function, , defined by :\beta(g) = \lambda\,\frac ~. This dependence on the energy scale is known as "the running of the coupling parameter", and theory of this systematic scale-dependence in quantum field theory is described by the renormalization group. Beta-functions are usually computed in an approximation scheme, most commonly perturbation theory, where one assumes that the coupling constant is small. One can then make an expansion in powers of the coupling parameters and truncate the higher-order terms (also known as higher loop contributions, due to the number of loops in the corresponding Feynman graphs). The -function at one loop (the first perturbative contribution) for the 4 theory is :\beta(g) = \fracg^2 + O\left(g^3\right) ~. The fact that the sign in front of the lowest-order term is positive suggests that the coupling constant increases with energy. If this behavior persisted at large couplings, this would indicate the presence of a Landau pole at finite energy, arising from
quantum triviality In a quantum field theory, charge screening can restrict the value of the observable "renormalized" charge of a classical theory. If the only resulting value of the renormalized charge is zero, the theory is said to be "trivial" or noninteracting. ...
. However, the question can only be answered non-perturbatively, since it involves strong coupling. A quantum field theory is said to be ''trivial'' when the renormalized coupling, computed through its beta function, goes to zero when the ultraviolet cutoff is removed. Consequently, the
propagator In quantum mechanics and quantum field theory, the propagator is a function that specifies the probability amplitude for a particle to travel from one place to another in a given period of time, or to travel with a certain energy and momentum. In ...
becomes that of a free particle and the field is no longer interacting. For a 4 interaction, Michael Aizenman proved that the theory is indeed trivial, for space-time dimension ≥ 5. For = 4, the triviality has yet to be proven rigorously, but lattice computations have provided strong evidence for this. This fact is important as
quantum triviality In a quantum field theory, charge screening can restrict the value of the observable "renormalized" charge of a classical theory. If the only resulting value of the renormalized charge is zero, the theory is said to be "trivial" or noninteracting. ...
can be used to bound or even ''predict'' parameters such as the
Higgs boson The Higgs boson, sometimes called the Higgs particle, is an elementary particle in the Standard Model of particle physics produced by the quantum excitation of the Higgs field, one of the fields in particle physics theory. In the Stand ...
mass. This can also lead to a predictable Higgs mass in
asymptotic safety Asymptotic safety (sometimes also referred to as nonperturbative renormalizability) is a concept in quantum field theory which aims at finding a consistent and predictive quantum theory of the gravitational field. Its key ingredient is a nontr ...
scenarios.


See also

* Renormalization *
Quantum triviality In a quantum field theory, charge screening can restrict the value of the observable "renormalized" charge of a classical theory. If the only resulting value of the renormalized charge is zero, the theory is said to be "trivial" or noninteracting. ...
* Landau pole * Scale invariance (CFT description) *
Scalar electrodynamics In theoretical physics, scalar electrodynamics is a theory of a U(1) gauge field coupled to a charged spin 0 scalar field that takes the place of the Dirac fermions in "ordinary" quantum electrodynamics. The scalar field is charged, and with an ap ...


Notes


References

* * * * * {{cite book, last=Zinn-Justin, first=J, author-link=Jean Zinn-Justin, title=Quantum Field Theory and Critical Phenomena, publisher=Oxford University Press, year=2002, isbn=978-0198509233


External links


The Conceptual Basis of Quantum Field Theory
Click on the link for Chap. 3 to find an extensive, simplified introduction to scalars in relativistic quantum mechanics and quantum field theory. Quantum field theory Mathematical physics Theoretical physics Scalars