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Line 1: {{Short description\|Mathematical operator in quantum optics}} ~~{{Context\|date=October 2009}}~~ In the [[quantum mechanics]] study of [[optical phase space]], the '''displacement operator''' for one mode is the [[shift operator]] in [[quantum optics]], {{Quantum optics operators}}▼ :<math>\hat{D}(\alpha)=\exp \left ( \alpha \hat{a}^\dagger - \alpha^\ast \hat{a} \right ) </math>, ▼ where <math>\alpha</math> is the amount of displacement in [[optical phase space]], <math>\alpha^~~\ast~~</math> is the complex conjugate of that displacement, and <math>\hat{a} </math> and <math>\hat{a}^\dagger</math> are the [[creation and annihilation operators\|lowering and raising operators]], respectively.▼ ~~The '''displacement operator''' for one mode in [[quantum optics]] is the [[operator]]~~ ▲:<math>\hat{D}(\alpha)=\exp \left ( \alpha \hat{a}^\dagger - \alpha^\ast \hat{a} \right ) </math>, ▲where <math>\alpha</math> is the amount of displacement in [[optical phase space]], <math>\alpha^\ast</math> is the complex conjugate of that displacement, and <math>\hat{a} </math> and <math>\hat{a}^\dagger</math> are the [[lowering and raising operators]], respectively. The name of this operator is derived from its ability to displace a localized state in phase space by a magnitude <math>\alpha</math>. It may also act on the vacuum state by displacing it into a [[coherent state]]. Specifically, <math>\hat{D}(\alpha)\|0\rangle=\|\alpha\rangle</math> where <math>\|\alpha\rangle</math> is a [[coherent state]], which is an [[eigenstate]] of the annihilation (lowering) operator. This operator was introduced independently by [[Richard Feynman]] and [[Roy J. Glauber]] in 1951.<ref>{{Cite journal \|last=Dodonov \|first=V. V. \|date=2002 \|title='Nonclassical' states in quantum optics: a 'squeezed' review of the first 75 years \|url=https://iopscience.iop.org/article/10.1088/1464-4266/4/1/201 \|journal=Journal of Optics B: Quantum and Semiclassical Optics \|volume=4 \|issue=1}}</ref><ref>{{Cite journal \|last=Feynman \|first=Richard P. \|date=1951-10-01 \|title=An Operator Calculus Having Applications in Quantum Electrodynamics \|url=https://journals.aps.org/pr/abstract/10.1103/PhysRev.84.108 \|journal=Physical Review \|volume=84 \|issue=1 \|pages=108–128 \|doi=10.1103/PhysRev.84.108\|url-access=subscription }}</ref><ref>{{Cite journal \|last=Glauber \|first=Roy J. \|date=1951-11-01 \|title=Some Notes on Multiple-Boson Processes \|url=https://journals.aps.org/pr/abstract/10.1103/PhysRev.84.395 \|journal=Physical Review \|volume=84 \|issue=3 \|pages=395–400 \|doi=10.1103/PhysRev.84.395\|url-access=subscription }}</ref> ~~<math>\hat{D}(\alpha)\|0\rangle=\|\alpha\rangle</math> where <math>=\|\alpha\rangle</math> is a coherent state.~~ ~~Displaced states are [[eigenfunctions]] of the annihilation (lowering) operator.~~ == Properties == The displacement operator is a [[unitary operator]], and therefore obeys <math>\hat{D}(\alpha)\hat{D}^\dagger(\alpha)=\hat{D}^\dagger(\alpha)\hat{D}(\alpha)=I\hat{1}</math>, where I<math>\hat{1}</math> is the identity ~~matrix~~operator. Since <math> \hat{D}^\dagger(\alpha)=\hat{D}(-\alpha)</math>, the [[hermitian conjugate]] of the displacement operator can also be interpreted as a displacement of opposite magnitude (<math>-\alpha</math>). The effect of applying this operator in a [[matrix similarity\|similarity transformation]] of the ladder operators results in their displacement. :<math>\hat{D}^\dagger(\alpha) \hat{a} \hat{D}(\alpha)=\hat{a}+\alpha</math~~><br~~> :<math>\hat{D}(\alpha) \hat{a} \hat{D}^\dagger(\alpha)=\hat{a}-\alpha</math> The product of two displacement operators is another displacement operator whose total displacement, ~~apart~~up ~~from~~to a phase factor, ~~has the total displacement as~~is the sum of the two individual displacements. This can be seen by utilizing the [[~~Baker-Campbell-Hausdorff formula#The Hadamard lemma\|Baker-Campbell-Hausdorff~~Baker–Campbell–Hausdorff formula]]. :<math> e^{\alpha \hat{Da}(^{\dagger} - \alpha)^\hat{Da}(} e^{\beta~~)=e~~\hat{a}^{\~~mathrm~~dagger} - i\~~cdot~~beta^\~~operatorname~~hat{Ima}} ~~\left~~= e^{(\alpha + \beta)\hat{a}^{\~~ast~~dagger} - (\~~right~~beta^+\alpha^)}\hat{Da}} e^{(\alpha + \beta^-\alpha^\beta)/2}. </math> which shows us that: When acting on an eigenket, the phase factor <math>e^{\mathrm i\cdot\operatorname{Im} \left(\alpha \beta^\ast \right)}</math> appears in each term of the resulting state, which makes it physically irrelevant.<ref>Gerry, Christopher, and Peter Knight: ''Introductory Quantum Optics''. Cambridge (England): Cambridge UP, 2005.</ref>▼ :<math>\hat{D}(\alpha)\hat{D}(\beta)= e^{(\alpha\beta^-\alpha^\beta)/2} \hat{D}(\alpha + \beta)</math> ▲When acting on an eigenket, the phase factor <math>e^{~~\mathrm i\cdot\operatorname{Im} \left~~(\alpha \beta^-\~~ast~~ alpha^\~~right~~beta)/2}</math> appears in each term of the resulting state, which makes it physically irrelevant.<ref>Christopher Gerry~~, Christopher,~~ and Peter Knight: ''Introductory Quantum Optics''. Cambridge (England): Cambridge UP, 2005.</ref> It further leads to the braiding relation :<math>\hat{D}(\alpha)\hat{D}(\beta)=e^{\alpha\beta^-\alpha^\beta} \hat{D}(\beta)\hat{D}(\alpha)</math> == Alternative expressions == The Kermack–McCrea identity (named after [[William Ogilvy Kermack]] and [[William McCrea (astronomer)\|William McCrea]]) gives two alternative ways to express the displacement operator: :<math>\hat{D}(\alpha) = e^{ -\frac{1}{2} \| \alpha \|^2 } e^{+\alpha \hat{a}^{\dagger}} e^{-\alpha^{} \hat{a} } </math> :<math>\hat{D}(\alpha) = e^{ +\frac{1}{2} \| \alpha \|^2 } e^{-\alpha^{} \hat{a} }e^{+\alpha \hat{a}^{\dagger}} </math> == Multimode displacement == The displacement operator can also be generalized to multimode displacement. A multimode creation operator can be defined as :<math>\hat A_{\psi}^{\dagger}=\int d\mathbf{k}\psi(\mathbf{k})\hat a^{\dagger}(\mathbf{k})</math>, ==References==▼ <references />▼ where <math>\mathbf{k}</math> is the wave vector and its magnitude is related to the frequency <math>\omega_{\mathbf{k}}</math> according to <math>\|\mathbf{k}\|=\omega_{\mathbf{k}}/c</math>. Using this definition, we can write the multimode displacement operator as ~~==Notes==~~ ==See also==▼ :<math>\hat{D}_{\psi}(\alpha)=\exp \left ( \alpha \hat A_{\psi}^{\dagger} - \alpha^\ast \hat A_{\psi} \right ) </math>, [[Optical Phase Space]]▼ and define the multimode coherent state as [[Category:Quantum optics]]▼ :<math>\|\alpha_{\psi}\rangle\equiv\hat{D}_{\psi}(\alpha)\|0\rangle</math>. ~~{{physics-stub}}~~ ▲==See also== ~~{{mathanalysis-stub}}~~ ▲* [[Optical ~~Phase~~phase ~~Space~~space]] ▲==References== ▲<references /> ▲{{~~Quantum optics~~Physics operators}} ▲[[Category:Quantum optics]]