The Ward–Takahashi identity applies to correlation functions in momentum space, which do not necessarily have all their external momenta on-shell. Let

${\displaystyle {\mathcal {M}}(k;p_{1}\cdots p_{n};q_{1}\cdots q_{n})=\epsilon _{\mu }(k){\mathcal {M}}^{\mu }(k;p_{1}\cdots p_{n};q_{1}\cdots q_{n})}$ 

be a QED correlation function involving an external photon with momentum k (where ${\displaystyle \epsilon _{\mu }(k)}$  is the polarization vector of the photon and summation over ${\displaystyle \mu =0,\ldots ,3}$  is implied), n initial-state electrons with momenta ${\displaystyle p_{1}\cdots p_{n}}$ , and n final-state electrons with momenta ${\displaystyle q_{1}\cdots q_{n}}$ . Also define ${\displaystyle {\mathcal {M}}_{0}}$  to be the simpler amplitude that is obtained by removing the photon with momentum k from our original amplitude. Then the Ward–Takahashi identity reads

${\displaystyle k_{\mu }{\mathcal {M}}^{\mu }(k;p_{1}\cdots p_{n};q_{1}\cdots q_{n})=e\sum _{i}\left[{\mathcal {M}}_{0}(p_{1}\cdots p_{n};q_{1}\cdots (q_{i}-k)\cdots q_{n})\right.}$ 

${\displaystyle \left.-{\mathcal {M}}_{0}(p_{1}\cdots (p_{i}+k)\cdots p_{n};q_{1}\cdots q_{n})\right]}$ 

where e is the charge of the electron and is negative in sign. Note that if ${\displaystyle {\mathcal {M}}}$  has its external electrons on-shell, then the amplitudes on the right-hand side of this identity each have one external particle off-shell, and therefore they do not contribute to S-matrix elements.

The Ward identity is a specialization of the Ward–Takahashi identity to S-matrix elements, which describe physically possible scattering processes and thus have all their external particles on-shell. Again let ${\displaystyle {\mathcal {M}}(k)=\epsilon _{\mu }(k){\mathcal {M}}^{\mu }(k)}$  be the amplitude for some QED process involving an external photon with momentum ${\displaystyle k}$ , where ${\displaystyle \epsilon _{\mu }(k)}$  is the polarization vector of the photon. Then the Ward identity reads:

${\displaystyle k_{\mu }{\mathcal {M}}^{\mu }(k)=0}$ 

Physically, what this identity means is the longitudinal polarization of the photon which arises in the ξ gauge is unphysical and disappears from the S-matrix.

Examples of its use include constraining the tensor structure of the vacuum polarization and of the electron vertex function in QED.

In the path integral formulation, the Ward–Takahashi identities are a reflection of the invariance of the functional measure under a gauge transformation. More precisely, if ${\displaystyle \delta _{\varepsilon }}$  represents a gauge transformation by ${\displaystyle \varepsilon }$  (and this applies even in the case where the physical symmetry of the system is global or even nonexistent; we are only worried about the invariance of the functional measure here), then

${\displaystyle \int \delta _{\varepsilon }\left({\mathcal {F}}e^{iS}\right){\mathcal {D}}\phi =0}$ 

expresses the invariance of the functional measure where ${\displaystyle S}$  is the action and ${\displaystyle {\mathcal {F}}}$  is a functional of the fields. If the gauge transformation corresponds to a global symmetry of the theory, then,

${\displaystyle \delta _{\varepsilon }S=\int \left(\partial _{\mu }\varepsilon \right)J^{\mu }\mathrm {d} ^{d}x=-\int \varepsilon \partial _{\mu }J^{\mu }\mathrm {d} ^{d}x}$ 

for some "current" J (as a functional of the fields ${\displaystyle \phi }$ ) after integrating by parts and assuming that the surface terms can be neglected.

Then, the Ward–Takahashi identities become

${\displaystyle \langle \delta _{\varepsilon }{\mathcal {F}}\rangle -i\int \varepsilon \langle {\mathcal {F}}\partial _{\mu }J^{\mu }\rangle \mathrm {d} ^{d}x=0}$ 

This is the QFT analog of the Noether continuity equation ${\displaystyle \partial _{\mu }J^{\mu }=0}$ .

If the gauge transformation corresponds to an actual gauge symmetry then

${\displaystyle \int \delta _{\varepsilon }\left({\mathcal {F}}e^{i\left(S+S_{gf}\right)}\right){\mathcal {D}}\phi =0}$ 

where ${\displaystyle S}$  is the gauge invariant action and ${\displaystyle S_{\mathrm {gf} }}$  is a non-gauge-invariant gauge fixing term.

But note that even if there is not a global symmetry (i.e. the symmetry is broken), we still have a Ward–Takahashi identity describing the rate of charge nonconservation.

If the functional measure is not gauge invariant, but happens to satisfy

${\displaystyle \int \delta _{\varepsilon }\left({\mathcal {F}}e^{iS}\right){\mathcal {D}}\phi =\int \varepsilon \lambda {\mathcal {F}}e^{iS}\mathrm {d} ^{d}x}$ 

where ${\displaystyle \lambda }$  is some functional of the fields ${\displaystyle \phi }$ , we have an anomalous Ward–Takahashi identity, for example when the fields have a chiral anomaly.