theoretical physics Theoretical physics is a branch of physics that employs mathematical models and abstractions of physical objects and systems to rationalize, explain and predict natural phenomena. This is in contrast to experimental physics, which uses experim ...

, Hamiltonian field theory is the field-theoretic analogue to classical

Hamiltonian mechanics Hamiltonian mechanics emerged in 1833 as a reformulation of Lagrangian mechanics. Introduced by Sir William Rowan Hamilton, Hamiltonian mechanics replaces (generalized) velocities \dot q^i used in Lagrangian mechanics with (generalized) ''momenta ...

. It is a formalism in classical field theory alongside Lagrangian field theory. It also has applications in quantum field theory.

Definition

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 ...

for a system of discrete particles is a function of their

generalized coordinates In analytical mechanics, generalized coordinates are a set of parameters used to represent the state of a system in a configuration space. These parameters must uniquely define the configuration of the system relative to a reference state.,p. 39 ...

and conjugate momenta, and possibly, time. For continua and fields, Hamiltonian mechanics is unsuitable but can be extended by considering a large number of point masses, and taking the continuous limit, that is, infinitely many particles forming a continuum or field. Since each point mass has one or more degrees of freedom, the field formulation has infinitely many degrees of freedom.

One scalar field

The Hamiltonian density is the continuous analogue for fields; it is a function of the fields, the conjugate "momentum" fields, and possibly the space and time coordinates themselves. For one scalar field , the Hamiltonian density is defined from the

Lagrangian density Lagrangian may refer to: Mathematics * Lagrangian function, used to solve constrained minimization problems in optimization theory; see Lagrange multiplier ** Lagrangian relaxation, the method of approximating a difficult constrained problem with ...

byIt is a standard abuse of notation to abbreviate all the derivatives and coordinates in the Lagrangian density as follows: :

\mathcal (\phi, \partial_\mu \phi, x_\mu)

The is an index which takes values 0 (for the time coordinate), and 1, 2, 3 (for the spatial coordinates), so strictly only one derivative or coordinate would be present. In general, all the spatial and time derivatives will appear in the Lagrangian density, for example in Cartesian coordinates, the Lagrangian density has the full form: :

\mathcal \left(\phi, \frac, \frac, \frac, \frac, x,y,z,t\right)

Here we write the same thing, but using ∇ to abbreviate all spatial derivatives as a vector. :

\mathcal(\phi, \pi, \mathbf,t) = \dot\pi - \mathcal(\phi, \nabla\phi, \partial \phi/\partial t , \mathbf,t)\,.

with the "del" or "nabla" operator, is the position vector of some point in space, and is

time Time is the continued sequence of existence and events that occurs in an apparently irreversible succession from the past, through the present, into the future. It is a component quantity of various measurements used to sequence events, ...

. The Lagrangian density is a function of the fields in the system, their space and time derivatives, and possibly the space and time coordinates themselves. It is the field analogue to the Lagrangian function for a system of discrete particles described by generalized coordinates. As in Hamiltonian mechanics where every generalized coordinate has a corresponding generalized momentum, the field has a conjugate momentum field , defined as the partial derivative of the Lagrangian density with respect to the time derivative of the field, :

\pi = \frac \,,\quad \dot\equiv\frac\,,

in which the overdotThis is standard notation in this context, most of the literature does not explicitly mention it is a partial derivative. In general total and partial time derivatives of a function are not the same. denotes a ''partial'' time derivative , not a total time derivative .

Many scalar fields

For many fields and their conjugates the Hamiltonian density is a function of them all: :

\mathcal(\phi_1,  \phi_2, \ldots, \pi_1, \pi_2, \ldots, \mathbf,t)= \sum_i\dot\pi_i - \mathcal(\phi_1,\phi_2,\ldots \nabla\phi_1,\nabla\phi_2,\ldots, \partial \phi_1/\partial t ,\partial \phi_2/\partial t ,\ldots, \mathbf,t)\,.

where each conjugate field is defined with respect to its field, :

\pi_i(\mathbf,t) = \frac \,.

In general, for any number of fields, the

volume integral In mathematics (particularly multivariable calculus), a volume integral (∭) refers to an integral over a 3-dimensional domain; that is, it is a special case of multiple integrals. Volume integrals are especially important in physics for many ...

of the Hamiltonian density gives the Hamiltonian, in three spatial dimensions: :

H = \int \mathcal \ d^3 x \,.

The Hamiltonian density is the Hamiltonian per unit spatial volume. The corresponding

dimension In physics and mathematics, the dimension of a mathematical space (or object) is informally defined as the minimum number of coordinates needed to specify any point within it. Thus, a line has a dimension of one (1D) because only one coor ...

is nergylength]⁻³, in SI units Joules per metre cubed, J m⁻³.

Tensor and spinor fields

The above equations and definitions can be extended to vector fields and more generally

tensor field In mathematics and physics, a tensor field assigns a tensor to each point of a mathematical space (typically a Euclidean space or manifold). Tensor fields are used in differential geometry, algebraic geometry, general relativity, in the analysis ...

s and

spinor field In differential geometry, given a spin structure on an n-dimensional orientable Riemannian manifold (M, g),\, one defines the spinor bundle to be the complex vector bundle \pi_\colon\to M\, associated to the corresponding principal bundle \pi_\col ...

s. In physics, tensor fields describe

boson In particle physics, a boson ( ) is a subatomic particle whose spin quantum number has an integer value (0,1,2 ...). Bosons form one of the two fundamental classes of subatomic particle, the other being fermions, which have odd half-integer spi ...

s and spinor fields describe fermions.

Equations of motion

The

equations of motion In physics, equations of motion are equations that describe the behavior of a physical system in terms of its motion as a function of time.''Encyclopaedia of Physics'' (second Edition), R.G. Lerner, G.L. Trigg, VHC Publishers, 1991, ISBN (Ver ...

for the fields are similar to the Hamiltonian equations for discrete particles. For any number of fields: where again the overdots are partial time derivatives, the

variational derivative In the calculus of variations, a field of mathematical analysis, the functional derivative (or variational derivative) relates a change in a functional (a functional in this sense is a function that acts on functions) to a change in a function on w ...

with respect to the fields :

\frac = \frac - \nabla\cdot \frac - \frac \frac \,,

with · the

dot product In mathematics, the dot product or scalar productThe term ''scalar product'' means literally "product with a scalar as a result". It is also used sometimes for other symmetric bilinear forms, for example in a pseudo-Euclidean space. is an alge ...

, must be used instead of simply partial derivatives. In

tensor index notation In mathematics, Ricci calculus constitutes the rules of index notation and manipulation for tensors and tensor fields on a differentiable manifold, with or without a metric tensor or connection. It is also the modern name for what used to be c ...

(including the

summation convention In mathematics, especially the usage of linear algebra in Mathematical physics, Einstein notation (also known as the Einstein summation convention or Einstein summation notation) is a notational convention that implies summation over a set of i ...

) this is :

\frac = \frac - \partial_\mu \frac

where is the

four-gradient In differential geometry, the four-gradient (or 4-gradient) \boldsymbol is the four-vector analogue of the gradient \vec from vector calculus. In special relativity and in quantum mechanics, the four-gradient is used to define the properties and r ...

Phase space

The fields and conjugates form an infinite dimensional phase space, because fields have an infinite number of degrees of freedom.

Poisson bracket

For two functions which depend on the fields and , their spatial derivatives, and the space and time coordinates, :

A = \int d^3 x \mathcal\left(\phi_1,\phi_2,\ldots,\pi_1,\pi_2,\ldots,\nabla\phi_1,\nabla\phi_2,\ldots,\nabla\pi_1,\nabla\pi_2,\ldots,\mathbf,t\right)\,,

B = \int d^3 x \mathcal\left(\phi_1,\phi_2,\ldots,\pi_1,\pi_2,\ldots,\nabla\phi_1,\nabla\phi_2,\ldots,\nabla\pi_1,\nabla\pi_2,\ldots,\mathbf,t\right)\,,

and the fields are zero on the boundary of the volume the integrals are taken over, the field theoretic Poisson bracket is defined as (not to be confused with the commutator from quantum mechanics). :

= \int d^3 x \sum_i \left(\frac\frac-\frac\frac\right)\,,

where

\delta \mathcal/\delta f

is the

\frac = \frac - \sum_i \nabla_i \frac \,.

Under the same conditions of vanishing fields on the surface, the following result holds for the time evolution of (similarly for ): :

+ \frac

which can be found from the total time derivative of ,

integration by parts In calculus, and more generally in mathematical analysis, integration by parts or partial integration is a process that finds the integral of a product of functions in terms of the integral of the product of their derivative and antiderivative. ...

, and using the above Poisson bracket.

Explicit time-independence

The following results are true if the Lagrangian and Hamiltonian densities are explicitly time-independent (they can still have implicit time-dependence via the fields and their derivatives),

Kinetic and potential energy densities

The Hamiltonian density is the total energy density, the sum of the kinetic energy density (

\mathcal

) and the potential energy density (

\mathcal

), :

\mathcal = \mathcal+\mathcal\,.

Continuity equation

Taking the partial time derivative of the definition of the Hamiltonian density above, and using the

chain rule In calculus, the chain rule is a formula that expresses the derivative of the composition of two differentiable functions and in terms of the derivatives of and . More precisely, if h=f\circ g is the function such that h(x)=f(g(x)) for every , ...

for

implicit differentiation In mathematics, an implicit equation is a relation of the form R(x_1, \dots, x_n) = 0, where is a function of several variables (often a polynomial). For example, the implicit equation of the unit circle is x^2 + y^2 - 1 = 0. An implicit func ...

and the definition of the conjugate momentum field, gives the continuity equation: :

\frac + \nabla\cdot \mathbf=0

in which the Hamiltonian density can be interpreted as the energy density, and :

\mathbf = \frac\frac

the energy flux, or flow of energy per unit time per unit surface area.

Relativistic field theory

Covariant Hamiltonian field theory is the relativistic formulation of Hamiltonian field theory. Hamiltonian field theory usually means the symplectic Hamiltonian formalism when applied to classical field theory, that takes the form of the instantaneous Hamiltonian formalism on an infinite-dimensional phase space, and where canonical coordinates are field functions at some instant of time. This Hamiltonian formalism is applied to quantization of fields, e.g., in quantum gauge theory. In Covariant Hamiltonian field theory,

canonical momenta 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_ ...

''p^μ_i'' corresponds to derivatives of fields with respect to all world coordinates ''x^μ''. Covariant Hamilton equations are equivalent to the Euler–Lagrange equations in the case of hyperregular Lagrangians. Covariant Hamiltonian field theory is developed in the Hamilton–De Donder, polysymplectic, multisymplectic and ''k''-symplecticRey, A., Roman-Roy, N. Saldago, M., Gunther's formalism (''k''-symplectic formalism) in classical field theory: Skinner-Rusk approach and the evolution operator, J. Math. Phys. 46 (2005) 052901. variants. A phase space of covariant Hamiltonian field theory is a finite-dimensional polysymplectic or multisymplectic manifold. Hamiltonian non-autonomous mechanics is formulated as covariant Hamiltonian field theory on

fiber bundles In mathematics, and particularly topology, a fiber bundle (or, in Commonwealth English: fibre bundle) is a space that is a product space, but may have a different topological structure. Specifically, the similarity between a space E and a p ...

over the time axis, i.e. the real line ℝ.

Notes

Citations

References

* * * *{{cite book , last1=Fetter, first1=A. L., last2=Walecka, first2=J. D., title=Theoretical Mechanics of Particles and Continua, year=1980, isbn= 978-0-486-43261-8, publisher=Dover, pages=258–259 Theoretical physics Mathematical physics Classical mechanics Classical field theory Quantum field theory Differential geometry