Quantum field theory |
---|
History |
Second quantization, also referred to as occupation number representation, is a formalism used to describe and analyze quantum many-body systems. In quantum field theory, it is known as canonical quantization, in which the fields (typically as the wave functions of matter) are thought of as field operators, in a manner similar to how the physical quantities (position, momentum, etc.) are thought of as operators in first quantization. The key ideas of this method were introduced in 1927 by Paul Dirac, [1] and were later developed, most notably, by Pascual Jordan [2] and Vladimir Fock. [3] [4] In this approach, the quantum many-body states are represented in the Fock state basis, which are constructed by filling up each single-particle state with a certain number of identical particles. [5] The second quantization formalism introduces the creation and annihilation operators to construct and handle the Fock states, providing useful tools to the study of the quantum many-body theory.
The starting point of the second quantization formalism is the notion of indistinguishability of particles in quantum mechanics. Unlike in classical mechanics, where each particle is labeled by a distinct position vector and different configurations of the set of s correspond to different many-body states, in quantum mechanics, the particles are identical, such that exchanging two particles, i.e. , does not lead to a different many-body quantum state. This implies that the quantum many-body wave function must be invariant (up to a phase factor) under the exchange of two particles. According to the statistics of the particles, the many-body wave function can either be symmetric or antisymmetric under the particle exchange:
This exchange symmetry property imposes a constraint on the many-body wave function. Each time a particle is added or removed from the many-body system, the wave function must be properly symmetrized or anti-symmetrized to satisfy the symmetry constraint. In the first quantization formalism, this constraint is guaranteed by representing the wave function as linear combination of permanents (for bosons) or determinants (for fermions) of single-particle states. In the second quantization formalism, the issue of symmetrization is automatically taken care of by the creation and annihilation operators, such that its notation can be much simpler.
Consider a complete set of single-particle wave functions labeled by (which may be a combined index of a number of quantum numbers). The following wave function
represents an N-particle state with the ith particle occupying the single-particle state . In the shorthanded notation, the position argument of the wave function may be omitted, and it is assumed that the ith single-particle wave function describes the state of the ith particle. The wave function has not been symmetrized or anti-symmetrized, thus in general not qualified as a many-body wave function for identical particles. However, it can be brought to the symmetrized (anti-symmetrized) form by operators for symmetrizer, and for antisymmetrizer.
For bosons, the many-body wave function must be symmetrized,
while for fermions, the many-body wave function must be anti-symmetrized,
Here is an element in the N-body permutation group (or symmetric group) , which performs a permutation among the state labels , and denotes the corresponding permutation sign. is the normalization operator that normalizes the wave function. (It is the operator that applies a suitable numerical normalization factor to the symmetrized tensors of degree n; see the next section for its value.)
If one arranges the single-particle wave functions in a matrix , such that the row-i column-j matrix element is , then the boson many-body wave function can be simply written as a permanent , and the fermion many-body wave function as a determinant (also known as the Slater determinant). [6]
First quantized wave functions involve complicated symmetrization procedures to describe physically realizable many-body states because the language of first quantization is redundant for indistinguishable particles. In the first quantization language, the many-body state is described by answering a series of questions like "Which particle is in which state?". However these are not physical questions, because the particles are identical, and it is impossible to tell which particle is which in the first place. The seemingly different states and are actually redundant names of the same quantum many-body state. So the symmetrization (or anti-symmetrization) must be introduced to eliminate this redundancy in the first quantization description.
In the second quantization language, instead of asking "each particle on which state", one asks "How many particles are there in each state?". Because this description does not refer to the labeling of particles, it contains no redundant information, and hence leads to a precise and simpler description of the quantum many-body state. In this approach, the many-body state is represented in the occupation number basis, and the basis state is labeled by the set of occupation numbers, denoted
meaning that there are particles in the single-particle state (or as ). The occupation numbers sum to the total number of particles, i.e. . For fermions, the occupation number can only be 0 or 1, due to the Pauli exclusion principle; while for bosons it can be any non-negative integer
The occupation number states are also known as Fock states. All the Fock states form a complete basis of the many-body Hilbert space, or Fock space. Any generic quantum many-body state can be expressed as a linear combination of Fock states.
Note that besides providing a more efficient language, Fock space allows for a variable number of particles. As a Hilbert space, it is isomorphic to the sum of the n-particle bosonic or fermionic tensor spaces described in the previous section, including a one-dimensional zero-particle space C.
The Fock state with all occupation numbers equal to zero is called the vacuum state, denoted . The Fock state with only one non-zero occupation number is a single-mode Fock state, denoted . In terms of the first quantized wave function, the vacuum state is the unit tensor product and can be denoted . The single-particle state is reduced to its wave function . Other single-mode many-body (boson) states are just the tensor product of the wave function of that mode, such as and . For multi-mode Fock states (meaning more than one single-particle state is involved), the corresponding first-quantized wave function will require proper symmetrization according to the particle statistics, e.g. for a boson state, and for a fermion state (the symbol between and is omitted for simplicity). In general, the normalization is found to be , where N is the total number of particles. For fermion, this expression reduces to as can only be either zero or one. So the first-quantized wave function corresponding to the Fock state reads
for bosons and
for fermions. Note that for fermions, only, so the tensor product above is effectively just a product over all occupied single-particle states.
The creation and annihilation operators are introduced to add or remove a particle from the many-body system. These operators lie at the core of the second quantization formalism, bridging the gap between the first- and the second-quantized states. Applying the creation (annihilation) operator to a first-quantized many-body wave function will insert (delete) a single-particle state from the wave function in a symmetrized way depending on the particle statistics. On the other hand, all the second-quantized Fock states can be constructed by applying the creation operators to the vacuum state repeatedly.
The creation and annihilation operators (for bosons) are originally constructed in the context of the quantum harmonic oscillator as the raising and lowering operators, which are then generalized to the field operators in the quantum field theory. [7] They are fundamental to the quantum many-body theory, in the sense that every many-body operator (including the Hamiltonian of the many-body system and all the physical observables) can be expressed in terms of them.
The creation and annihilation of a particle is implemented by the insertion and deletion of the single-particle state from the first quantized wave function in an either symmetric or anti-symmetric manner. Let be a single-particle state, let 1 be the tensor identity (it is the generator of the zero-particle space C and satisfies in the tensor algebra over the fundamental Hilbert space), and let be a generic tensor product state. The insertion and the deletion operators are linear operators defined by the following recursive equations
Here is the Kronecker delta symbol, which gives 1 if , and 0 otherwise. The subscript of the insertion or deletion operators indicates whether symmetrization (for bosons) or anti-symmetrization (for fermions) is implemented.
The boson creation (resp. annihilation) operator is usually denoted as (resp. ). The creation operator adds a boson to the single-particle state , and the annihilation operator removes a boson from the single-particle state . The creation and annihilation operators are Hermitian conjugate to each other, but neither of them are Hermitian operators ().
The boson creation (annihilation) operator is a linear operator, whose action on a N-particle first-quantized wave function is defined as
where inserts the single-particle state in possible insertion positions symmetrically, and deletes the single-particle state from possible deletion positions symmetrically.
Hereinafter the tensor symbol between single-particle states is omitted for simplicity. Take the state , create one more boson on the state ,
Then annihilate one boson from the state ,
Starting from the single-mode vacuum state , applying the creation operator repeatedly, one finds
The creation operator raises the boson occupation number by 1. Therefore, all the occupation number states can be constructed by the boson creation operator from the vacuum state
On the other hand, the annihilation operator lowers the boson occupation number by 1
It will also quench the vacuum state as there has been no boson left in the vacuum state to be annihilated. Using the above formulae, it can be shown that
meaning that defines the boson number operator.
The above result can be generalized to any Fock state of bosons.
These two equations can be considered as the defining properties of boson creation and annihilation operators in the second-quantization formalism. The complicated symmetrization of the underlying first-quantized wave function is automatically taken care of by the creation and annihilation operators (when acting on the first-quantized wave function), so that the complexity is not revealed on the second-quantized level, and the second-quantization formulae are simple and neat.
The following operator identities follow from the action of the boson creation and annihilation operators on the Fock state,
These commutation relations can be considered as the algebraic definition of the boson creation and annihilation operators. The fact that the boson many-body wave function is symmetric under particle exchange is also manifested by the commutation of the boson operators.
The raising and lowering operators of the quantum harmonic oscillator also satisfy the same set of commutation relations, implying that the bosons can be interpreted as the energy quanta (phonons) of an oscillator. The position and momentum operators of a Harmonic oscillator (or a collection of Harmonic oscillating modes) are given by Hermitian combinations of phonon creation and annihilation operators,
which reproduce the canonical commutation relation between position and momentum operators (with )
This idea is generalized in the quantum field theory, which considers each mode of the matter field as an oscillator subject to quantum fluctuations, and the bosons are treated as the excitations (or energy quanta) of the field.
The fermion creation (annihilation) operator is usually denoted as (). The creation operator adds a fermion to the single-particle state , and the annihilation operator removes a fermion from the single-particle state .
The fermion creation (annihilation) operator is a linear operator, whose action on a N-particle first-quantized wave function is defined as
where inserts the single-particle state in possible insertion positions anti-symmetrically, and deletes the single-particle state from possible deletion positions anti-symmetrically.
It is particularly instructive to view the results of creation and annihilation operators on states of two (or more) fermions, because they demonstrate the effects of exchange. A few illustrative operations are given in the example below. The complete algebra for creation and annihilation operators on a two-fermion state can be found in Quantum Photonics. [8]
Hereinafter the tensor symbol between single-particle states is omitted for simplicity. Take the state , attempt to create one more fermion on the occupied state will quench the whole many-body wave function,
Annihilate a fermion on the state, take the state ,
The minus sign (known as the fermion sign) appears due to the anti-symmetric property of the fermion wave function.
Starting from the single-mode vacuum state , applying the fermion creation operator ,
If the single-particle state is empty, the creation operator will fill the state with a fermion. However, if the state is already occupied by a fermion, further application of the creation operator will quench the state, demonstrating the Pauli exclusion principle that two identical fermions can not occupy the same state simultaneously. Nevertheless, the fermion can be removed from the occupied state by the fermion annihilation operator ,
The vacuum state is quenched by the action of the annihilation operator.
Similar to the boson case, the fermion Fock state can be constructed from the vacuum state using the fermion creation operator
It is easy to check (by enumeration) that
meaning that defines the fermion number operator.
The above result can be generalized to any Fock state of fermions.
Recall that the occupation number can only take 0 or 1 for fermions. These two equations can be considered as the defining properties of fermion creation and annihilation operators in the second quantization formalism. Note that the fermion sign structure , also known as the Jordan-Wigner string, requires there to exist a predefined ordering of the single-particle states (the spin structure)[ clarification needed ] and involves a counting of the fermion occupation numbers of all the preceding states; therefore the fermion creation and annihilation operators are considered non-local in some sense. This observation leads to the idea that fermions are emergent particles in the long-range entangled local qubit system. [10]
The following operator identities follow from the action of the fermion creation and annihilation operators on the Fock state,
These anti-commutation relations can be considered as the algebraic definition of the fermion creation and annihilation operators. The fact that the fermion many-body wave function is anti-symmetric under particle exchange is also manifested by the anti-commutation of the fermion operators.
The creation and annihilation operators are Hermitian conjugate to each other, but neither of them are Hermitian operators (). The Hermitian combination of the fermion creation and annihilation operators
are called Majorana fermion operators. They can be viewed as the fermionic analog of position and momentum operators of a "fermionic" Harmonic oscillator. They satisfy the anticommutation relation
where labels any Majorana fermion operators on equal footing (regardless their origin from Re or Im combination of complex fermion operators ). The anticommutation relation indicates that Majorana fermion operators generates a Clifford algebra, which can be systematically represented as Pauli operators in the many-body Hilbert space.
Defining as a general annihilation (creation) operator for a single-particle state that could be either fermionic or bosonic , the real space representation of the operators defines the quantum field operators and by
These are second quantization operators, with coefficients and that are ordinary first-quantization wavefunctions. Thus, for example, any expectation values will be ordinary first-quantization wavefunctions. Loosely speaking, is the sum of all possible ways to add a particle to the system at position r through any of the basis states , not necessarily plane waves, as below.
Since and are second quantization operators defined in every point in space they are called quantum field operators. They obey the following fundamental commutator and anti-commutator relations,
For homogeneous systems it is often desirable to transform between real space and the momentum representations, hence, the quantum fields operators in Fourier basis yields:
The term "second quantization", introduced by Jordan, [11] is a misnomer that has persisted for historical reasons. At the origin of quantum field theory, it was inappositely thought that the Dirac equation described a relativistic wavefunction (hence the obsolete "Dirac sea" interpretation), rather than a classical spinor field which, when quantized (like the scalar field), yielded a fermionic quantum field (vs. a bosonic quantum field).
One is not quantizing "again", as the term "second" might suggest; the field that is being quantized is not a Schrödinger wave function that was produced as the result of quantizing a particle, but is a classical field (such as the electromagnetic field or Dirac spinor field), essentially an assembly of coupled oscillators, that was not previously quantized. One is merely quantizing each oscillator in this assembly, shifting from a semiclassical treatment of the system to a fully quantum-mechanical one.
In quantum mechanics, bra–ket notation, or Dirac notation, is used ubiquitously to denote quantum states. The notation uses angle brackets, and , and a vertical bar , to construct "bras" and "kets".
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, it is one of the most important model systems in quantum mechanics. Furthermore, it is one of the few quantum-mechanical systems for which an exact, analytical solution is known.
In quantum physics, a wave function is a mathematical description of the quantum state of an isolated quantum system. The wave function is a complex-valued probability amplitude, and the probabilities for the possible results of measurements made on the system can be derived from it. The most common symbols for a wave function are the Greek letters ψ and Ψ.
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 H. It is named after V. A. Fock who first introduced it in his 1932 paper "Konfigurationsraum und zweite Quantelung".
In quantum mechanics, a Fock state or number state is a quantum state that is an element of a Fock space with a well-defined number of particles. These states are named after the Soviet physicist Vladimir Fock. Fock states play an important role in the second quantization formulation of quantum mechanics.
In physics, the S-matrix or scattering matrix relates the initial state and the final state of a physical system undergoing a scattering process. It is used in quantum mechanics, scattering theory and quantum field theory (QFT).
Creation operators and annihilation operators are mathematical operators that have widespread applications in quantum mechanics, notably in the study of quantum harmonic oscillators and many-particle systems. An annihilation operator lowers the number of particles in a given state by one. A creation operator increases the number of particles in a given state by one, and it is the adjoint of the annihilation operator. In many subfields of physics and chemistry, the use of these operators instead of wavefunctions is known as second quantization. They were introduced by Paul Dirac.
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.
In quantum field theory, the Lehmann–Symanzik–Zimmerman (LSZ) reduction formula is a method to calculate S-matrix elements from the time-ordered correlation functions of a quantum field theory. It is a step of the path that starts from the Lagrangian of some quantum field theory and leads to prediction of measurable quantities. It is named after the three German physicists Harry Lehmann, Kurt Symanzik and Wolfhart Zimmermann.
In quantum mechanics, a two-state system is a quantum system that can exist in any quantum superposition of two independent quantum states. The Hilbert space describing such a system is two-dimensional. Therefore, a complete basis spanning the space will consist of two independent states. Any two-state system can also be seen as a qubit.
This article describes the mathematics of the Standard Model of particle physics, a gauge quantum field theory containing the internal symmetries of the unitary product group SU(3) × SU(2) × U(1). The theory is commonly viewed as describing the fundamental set of particles – the leptons, quarks, gauge bosons and the Higgs boson.
In quantum field theory, a fermionic field is a quantum field whose quanta are fermions; that is, they obey Fermi–Dirac statistics. Fermionic fields obey canonical anticommutation relations rather than the canonical commutation relations of bosonic fields.
In many-body theory, the term Green's function is sometimes used interchangeably with correlation function, but refers specifically to correlators of field operators or creation and annihilation operators.
In quantum mechanics, a raising or lowering operator is an operator that increases or decreases the eigenvalue of another operator. In quantum mechanics, the raising operator is sometimes called the creation operator, and the lowering operator the annihilation operator. Well-known applications of ladder operators in quantum mechanics are in the formalisms of the quantum harmonic oscillator and angular momentum.
In quantum mechanics and quantum field theory, a Schrödinger field, named after Erwin Schrödinger, is a quantum field which obeys the Schrödinger equation. While any situation described by a Schrödinger field can also be described by a many-body Schrödinger equation for identical particles, the field theory is more suitable for situations where the particle number changes.
Spin is a conserved quantity carried by elementary particles, and thus by composite particles (hadrons) and atomic nuclei.
The quantization of the electromagnetic field, means that an electromagnetic field consists of discrete energy parcels, photons. Photons are massless particles of definite energy, definite momentum, and definite spin.
In quantum physics, a quantum state is a mathematical entity that provides a probability distribution for the outcomes of each possible measurement on a system. Knowledge of the quantum state together with the rules for the system's evolution in time exhausts all that can be predicted about the system's behavior. A mixture of quantum states is again a quantum state. Quantum states that cannot be written as a mixture of other states are called pure quantum states, while all other states are called mixed quantum states. A pure quantum state can be represented by a ray in a Hilbert space over the complex numbers, while mixed states are represented by density matrices, which are positive semidefinite operators that act on Hilbert spaces.
This is a glossary for the terminology often encountered in undergraduate quantum mechanics courses.
In pure and applied mathematics, quantum mechanics and computer graphics, a tensor operator generalizes the notion of operators which are scalars and vectors. A special class of these are spherical tensor operators which apply the notion of the spherical basis and spherical harmonics. The spherical basis closely relates to the description of angular momentum in quantum mechanics and spherical harmonic functions. The coordinate-free generalization of a tensor operator is known as a representation operator.