Wick's theorem

Wick's theorem is a method of reducing high-order derivatives to a combinatorics problem.(Philips, 2001) It is named after Gian-Carlo Wick. It is used extensively in quantum field theory to reduce arbitrary products of creation and annihilation operators to sums of products of pairs of these operators. This allows for the use of Green's function methods, and consequently the use of Feynman diagrams in the field under study.

Definition of contraction

For two operators $hat{A}$ and $hat{B}$ we define their contraction to be: $hat{A}^ullet, hat{B}^ullet equiv hat{A},hat{B}, - : hat{A},hat{B} :$

where $: hat{O} :$ denotes the normal order of operator $hat{O}$

There is alternative notation for this as a line joining $hat{A}$ and $hat{B}$ .

We shall look in detail at four special cases where $hat{A}$ and $hat{B}$ are equal to creation and annihilation operators. For $N$ particles we'll denote the creation operators by $hat{a}_i^dagger$ and the annihilation operators by $hat{a}_i$ ( $i=1,ldots,N$ ).

We then have

: $hat{a}_i^ullet ,hat{a}_j^ullet = hat{a}_i ,hat{a}_j ,- :,hat{a}_i, hat{a}_j,:, = 0$ : $hat{a}_i^{daggerullet}, hat{a}_j^{daggerullet} = hat{a}_i^dagger, hat{a}_j^dagger ,-,:hat{a}_i^dagger,hat{a}_j^dagger,:, = 0$ : $hat{a}_i^{daggerullet}, hat{a}_j^ullet = hat{a}_i^dagger, hat{a}_j ,- :,hat{a}_i^dagger ,hat{a}_j, :,= 0$ : $hat{a}_i^ullet ,hat{a}_j^{daggerullet}= hat{a}_i, hat{a}_j^dagger ,- :,hat{a}_i,hat{a}_j^dagger ,:, = delta_{ij}$ where $i,j = 1,ldots,N$ and $delta_{ij}$ denotes the Kronecker delta.

These relationships hold true for bosonic operators or fermionic operators because of the way normal ordering is defined.

Wick's theorem

We can use contractions and normal ordering to express any product of creation and annihilation operators as a sum of normal ordered terms. This is the basis of Wick's theorem. Before stating the theorem fully we shall look at some examples.

Examples

Suppose $hat{a}_i$ and $hat{a}_i^dagger$ ( $i=1,ldots,N$ ) are bosonic operators satisfying the commutation relations:: $left [hat{a}_i^dagger, hat{a}_j^dagger
ight] _- = 0$ : $left [hat{a}_i, hat{a}_j
ight] _- = 0$ : $left [hat{a}_i, hat{a}_j^dagger
ight ] _- = delta_{ij}$ where $i,j = 1,ldots,N$ , $left [ A, B
ight] _i equiv AB - BA$ denotes the commutator and $delta_{ij}$ denotes the Kronecker delta.

We can use these relations, and the above definition of contraction, to express products of $hat{a}_i$ and $hat{a}_i^dagger$ in other ways.

"Example 1"

: $hat{a}_i ,hat{a}_j^dagger = hat{a}_j^dagger ,hat{a}_i + delta_{ij} = hat{a}_j^dagger ,hat{a}_i + hat{a}_i^ullet ,hat{a}_j^{daggerullet} =,:,hat{a}_i, hat{a}_j^dagger ,: + hat{a}_i^ullet ,hat{a}_j^{daggerullet}$

Note that we have not changed $hat{a}_i ,hat{a}_j^dagger$ but merely re-expressed it in another form as $,:,hat{a}_i, hat{a}_j^dagger ,: + hat{a}_i^ullet ,hat{a}_j^{daggerullet}$ .

"Example 2"

: $hat{a}_i ,hat{a}_j^dagger , hat{a}_k= (hat{a}_j^dagger ,hat{a}_i + delta_{ij})hat{a}_k = hat{a}_j^dagger ,hat{a}_i, hat{a}_k + delta_{ij}hat{a}_k = hat{a}_j^dagger ,hat{a}_i,hat{a}_k + hat{a}_i^ullet ,hat{a}_j^{daggerullet} hat{a}_k =,:,hat{a}_i, hat{a}_j^dagger hat{a}_k ,: + hat{a}_i^ullet ,hat{a}_j^{daggerullet} ,hat{a}_k$

"Example 3"

: $hat{a}_i ,hat{a}_j^dagger , hat{a}_k ,hat{a}_l^dagger= (hat{a}_j^dagger ,hat{a}_i + delta_{ij})(hat{a}_l^dagger,hat{a}_k + delta_{kl}) = hat{a}_j^dagger ,hat{a}_i, hat{a}_l^dagger, hat{a}_k + delta_{kl}hat{a}_j^dagger ,hat{a}_i + delta_{ij}hat{a}_l^daggerhat{a}_k + delta_{ij} delta_{kl}$ : $= hat{a}_j^dagger (hat{a}_l^dagger, hat{a}_i + delta_{il}) hat{a}_k + delta_{kl}hat{a}_j^dagger ,hat{a}_i + delta_{ij}hat{a}_l^daggerhat{a}_k + delta_{ij} delta_{kl}$ : $= hat{a}_j^dagger hat{a}_l^dagger, hat{a}_i hat{a}_k + delta_{il} hat{a}_j^dagger , hat{a}_k + delta_{kl}hat{a}_j^dagger ,hat{a}_i + delta_{ij}hat{a}_l^daggerhat{a}_k + delta_{ij} delta_{kl}$ : $= ,:hat{a}_i ,hat{a}_j^dagger , hat{a}_k ,hat{a}_l^dagger,: + :,hat{a}_i^ullet ,hat{a}_j^dagger , hat{a}_k ,hat{a}_l^{daggerullet},:+:,hat{a}_i ,hat{a}_j^dagger , hat{a}_k^ullet ,hat{a}_l^{daggerullet},:+:,hat{a}_i^ullet ,hat{a}_j^{daggerullet} , hat{a}_k ,hat{a}_l^dagger,:+ ,:hat{a}_i^ullet ,hat{a}_j^{daggerullet} , hat{a}_k^{ulletullet},hat{a}_l^{daggerulletullet},:$

In the last line we have used different numbers of $^ullet$ symbols to denote different contractions. By repeatedly applying the commutation relations it takes a lot of work, as you can see, to express $hat{a}_i ,hat{a}_j^dagger , hat{a}_k ,hat{a}_l^dagger$ in the form of a sum of normally ordered products. It is an even lengthier calculation for more complicated products.

Luckily Wick's theorem provides a short cut.

tatement of the theorem

For a product of creation and annihilation operators $hat{A} hat{B} hat{C} hat{D} hat{E} hat{F}ldots$ we can express it as

: $egin{array}{ll} hat{A} hat{B} hat{C} hat{D} hat{E} hat{F}ldots & = ,: hat{A} hat{B} hat{C} hat{D} hat{E} hat{F}ldots ,: \& + sum_{singles} ,: hat{A}^ullet hat{B}^{ullet} hat{C} hat{D} hat{E} hat{F}ldots ,: \ & + sum_{doubles} ,: hat{A}^ullet hat{B}^{ulletullet} hat{C}^{ulletullet} hat{D}^ullet hat{E} hat{F}ldots ,: \& +ldots end{array}$

In words, this theorem states that a string of creation and annihilation operators can be rewritten as the normal ordered product of the string, plus the normal-ordered product after all single contractions among operator pairs, plus all double contractions, etc, plus all full contractions.

Applying the theorem to the above examples provides a much quicker method to arrive at the final expressions.

A warning: In terms on the right hand side containing multiple contractions care must be taken when the operators are fermionic. In this case an appropriate minus sign must be introduced according to the following rule: rearrange the operators (introducing minus signs whenever the order of two fermionic operators is swapped) to ensure the contracted terms are adjacent in the string. The contraction can then be applied (See Rule C" in Wick's paper).

Example:

If we have two fermions ( $N=2$ ) with creation and annihilation operators $hat{f}_i^dagger$ and $hat{f}_i$ ( $i=1,2$ ) then

: $egin{array}{ll} hat{f}_1 ,hat{f}_2 , hat{f}_1^dagger ,hat{f}_2^dagger ,&= ,: hat{f}_1 ,hat{f}_2 , hat{f}_1^dagger ,hat{f}_2^dagger , : \ & + ,: hat{f}_1^ullet ,hat{f}_2 , hat{f}_1^{daggerullet} ,hat{f}_2^dagger , : + ,: hat{f}_1^ullet ,hat{f}_2 , hat{f}_1^dagger ,hat{f}_2^{daggerullet} , : +,: hat{f}_1 ,hat{f}_2^ullet , hat{f}_1^{daggerullet} ,hat{f}_2^dagger , : + : hat{f}_1 ,hat{f}_2^ullet , hat{f}_1^dagger ,hat{f}_2^{daggerullet} , : \ & -: hat{f}_1^{ulletullet} ,hat{f}_2^ullet , hat{f}_1^{daggerulletullet} ,hat{f}_2^{daggerullet} , :+: hat{f}_1^{ulletullet} ,hat{f}_2^ullet , hat{f}_1^{daggerullet} ,hat{f}_2^{daggerulletullet}: end{array}$

Wick's theorem applied to fields

: $mathcal C(x_1, x_2)=left langle 0 |mathcal Tphi_i(x_1)phi_i(x_2)|0
ight
angle=overline{phi_i(x_1)phi_i(x_2)}=iDelta_F(x_1-x_2)=iint{frac{d^4k}{(2pi)^4}frac{e^{-ik(x_1-x_2){(k^2-m^2)+iepsilon.$

Which means that $overline{AB}=mathcal TAB-:AB:$

In the end, we arrive at Wick's theorem:

The T-product of a time-ordered free fields string can be expressed in the following manner:

: $mathcal TPi_{k=1}^mphi(x_k)=:Piphi_i(x_k):+sum_{alpha,eta}overline{phi(x_alpha)phi(x_eta)}:Pi_{k
ot=alpha,eta}phi_i(x_k):+$

: $mathcal+sum_{(alpha,eta),(gamma,delta)}overline{phi(x_alpha)phi(x_eta)};overline{phi(x_gamma)phi(x_delta)}:Pi_{k
ot=alpha,eta,gamma,delta}phi_i(x_k):+cdots.$

Applying this theorem to S-matrix elements, we discover that normal-ordered terms acting on vacuum state give a null contribution to the sum. We conclude that "m" is even and only completely contracted terms remain.

: $F_m^i(x)=left langle 0 |mathcal Tphi_i(x_1)phi_i(x_2)|0
ight
angle=sum_mathrm{pairs}overline{phi(x_1)phi(x_2)}cdotsoverline{phi(x_{m-1})phi(x_m})$

: $G_p^{(n)}=left langle 0 |mathcal T:v_i(y_1):dots:v_i(y_n):phi_i(x_1)cdots phi_i(x_p)|0
ight
angle$

where "p" is the number of interaction fields (or, equivalently, the number of interacting particles) and "n" is the development order (or the number of vertices of interaction). For example, if $v=gy^4 Rightarrow :v_i(y_1):=:phi_i(y_1)phi_i(y_1)phi_i(y_1)phi_i(y_1):$

This is analogous to the corresponding theorem in statistics for the moments of a Gaussian distribution.

Bibliography

* G.C. Wick, [http://link.aps.org/abstract/PR/v80/p268 The Evaluation of the Collision Matrix] , Phys. Rev. 80, 268 - 272 (1950)

* S.S. Schweber, An Introduction to Relativistic Quantum Field Theory, Harper and Row, New York (1962). (Chapter 13, Sec c)

ee also

*S matrix
*Normal order

Wikimedia Foundation. 2010.

Игры ⚽ Поможем написать реферат

Look at other dictionaries:

Wick’s theorem — Viko teorema statusas T sritis fizika atitikmenys: angl. Wick’s theorem vok. Wickscher Satz, m rus. теорема Вика, f pranc. théorème de Wick, m … Fizikos terminų žodynas
Wick product — In probability theory, the Wick product:langle X 1,dots,X k angle,named after physicist Gian Carlo Wick, is a sort of product of the random variables, X 1, ..., X k , defined recursively as follows::langle angle = 1,(i.e. the empty product… … Wikipedia
Gian-Carlo Wick — (1909 1992) was an Italian theoretical physicist. The Wick rotation, Wick s theorem, and the Wick product are named after him.External links* [http://stills.nap.edu/html/biomems/gwick.html Wick s biography at the website of National Academies… … Wikipedia
théorème de Wick — Viko teorema statusas T sritis fizika atitikmenys: angl. Wick’s theorem vok. Wickscher Satz, m rus. теорема Вика, f pranc. théorème de Wick, m … Fizikos terminų žodynas
Gian-Carlo Wick — Gian Carlo Wick, 1963 in Kopenhagen Gian Carlo Wick (* 15. Oktober 1909 in Turin; † 20. April 1992 in Turin) war ein italienischer Physiker, der wichtige Beiträge zur Quantenfeldtheorie leistete … Deutsch Wikipedia
Bell's theorem — is a theorem that shows that the predictions of quantum mechanics (QM) are not intuitive, and touches upon fundamental philosophical issues that relate to modern physics. It is the most famous legacy of the late physicist John S. Bell. Bell s… … Wikipedia
Feynman diagram — The Wick s expansion of the integrand gives (among others) the following termNarpsi(x)gamma^mupsi(x)arpsi(x )gamma^ upsi(x )underline{A mu(x)A u(x )};,whereunderline{A mu(x)A u(x )}=int{d^4pover(2pi)^4}{ig {mu u}over k^2+i0}e^{ k(x x )}is the… … Wikipedia
Normal order — For other uses, see Normal order (disambiguation). 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… … Wikipedia
Debashis Mukherjee — At the 12th ICQC in Kyoto, 2006 Born 17 December 1946( … Wikipedia
Wightman axioms — Quantum field theory (Feynman diagram) … Wikipedia

Academic Dictionaries and Encyclopedias

Wick's theorem

Look at other dictionaries:

Share the article and excerpts

Academic Dictionaries and Encyclopedias

Wikipedia

Wick's theorem

Look at other dictionaries:

Share the article and excerpts

Direct link