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    Influence of Partial Coherent Light on the Transmission Spectrum and Goos-H¨anchen Shift in Rydberg Atomic Medium

    2019-03-12 02:41:12DilawarAliMuhammadUmerIftikharMuqaddarAbbasandZiauddin
    Communications in Theoretical Physics 2019年3期

    Dilawar Ali, Muhammad Umer Iftikhar, Muqaddar Abbas, and Ziauddin

    Quantum Optics Laboratory, Department of Physics, COMSATS University, Islamabad, Pakistan

    (Received August 31, 2018; revised manuscript received September 19, 2018)

    Abstract A cold atomic medium (Rydberg medium)with cascade configuration under the blockade mechanism is considered.A partial coherent light (PCL)beam is incident on the medium, which makes an angle θ with z-axis.We study the influence of PCL field on the transmission spectrum and find high transmission of probe field for PCL field.Conversely, it is investigated that the transparency of probe field decrease for coherent light field.The transmission of probe field is also studied via beam width of PCL field and investigated high transmission of probe field for small beam width and vice versa.Interestingly, the Goos-H¨anchen shift (GHS)in the transmitted light (TL)is studied for PCL field.Large negative and positive GHS in the TL are investigated for PCL field and small beam width of PCL field.

    Key words: partial coherent light, transmission spectrum, Goos-Hanchen shift

    1 Introduction

    A state which has a high principle quantum number is known as Rydberg state.[1]The most important characteristic of Rydberg atom is the strong interaction of one Rydberg atom to the other.For such a strong interaction, only one excited Rydberg atom can suppress the other excitation of Rydberg atoms in a small volume,which is known as dipole blockade.[2]To address electromagnetically induced transparency (EIT)in atomic system, the Rydberg states have exhibited important characteristics such as strong dipole-dipole interactions, long radiative life time as well as the van der waals (vdW)interactions.[3]The characteristics of highly Rydberg excitations have significant role in information processing as well as in quantum gates,[4?6]many body effects,[7?9]and light atom quantum interface.[10?12]

    In the above investigations, major part is dependent on the dipole blockade phenomenon.[13?14]In earlier studies, it has been revealed that the blockade phenomenon of Rydberg atom becomes a good candidate for devices like single photon sources, single photon switches, and photon filters.[15?17]Earlier, an experiment has been done in which a strong vdW interaction has been considered in atomic Rydberg medium.[18]In the experiment, a reduction in the transmission spectrum has been observed via increasing the intensity of input probe field.The authors of this experiment have no clear evidence of the reduction of transmission spectrum via increasing the probe field intensity.Later, this erratic reduction of the transmission spectrum via increasing the probe field intensity has been explained by considering a theoretical model based on the blockade phenomenon.[19]Further, the transmission of probe field has been studied in optomechanical systems.[20?21]and investigated enhanced generation of higher-order side bands.

    In addition, the Goos-H¨anchen shift (GHS)is a process when a light experiences a tiny displacement (shift)in the phenomenon of total internal reflection.This tiny shift has been observed by Goos and H¨anchen[22]in total internal reflection in the interface of two media.After the observation of Goos and H¨anchen, the GHS has been studied in different structure.[23?30]The GHS has been emerged substantial interests due to its potential applications in optical sensing such as measurement of the refractive index,beam angle,irregularities and roughness of the surface of a medium.[28]In last couples of years, the GHS has been investigated by considering atomic media and quantum well systems in a cavity.[31?38]

    We consider an atomic medium consists of threelevel Rydberg atoms and study the effect of PCL field on the transmission spectrum.The motivation comes from earlier investigations[18?19]where a coherent light has been used and studied the transmission of probe field through Rydberg atomic medium.In some other investigations,[39?41]the GHS and diffraction grating have been studied using PCL field.In the present work, we expect high transmission of probe field for PCL while low transmission for coherent light.Similarly, we also expect giant GHS in the TL for PCL field.

    2 Model

    We consider a light beamEm(z,y)having a mode indexmfalls on the atomic ensemble of Rydberg atoms as shown in see Fig.1(a).The required electric field equation can be written as

    where

    represents the angular spectrum for a proposed PCL beam,which can be calculated by taking the Fourier transform of√whereasHmrepresents the Hermite polynomials andkyis the wave vector of theycomponent.Here,wsandwgare the beam width and spectral coherence width of partially coherent light beam, respectively.Similarly,ccan be defined asc= (q2+ 4)1/2/[4qw2ssec2(φ)] whereq=wg/ws.The expression for probe field transmission can be expressed as

    In order to investigate the GHS in the TL, we use the stationary phase theory where for the incident beam i.e,Eq.(1)has large width and narrow angular spectrum that can be represented as[31?32]

    whereφTis the phase of the transmission coefficient.Further, we can also represent the above expression in the form as

    whereθbe the incident angle.

    Fig.1 (Color online)(a)Schematics of PCL beam incident on a medium; (b)the energy-level configuration of a threelevel Rydberg atom.

    2.1 Atom-Field Interaction

    We consider an atomic medium where each atom consists of cold rubidium (87Rb)atoms in a cascade configuration.The medium is interacting with probe and control fields as shown in Fig.1(b).The energy-level of each atom can be represented by|1>,|2>,and|3>.A probe field is applied between|1>and|2>having Rabi frequency ?pwhereas the control field is applied between|3>and|2>and having Rabi frequency ?c.The corresponding control field can excite the atoms to the Rydberg state|3>and the interaction between the atoms can occur via a potential|?(rrri ?rrrj)=C6/|rrri ?rrrj|6which is called a vdW potential.[19]The total Hamiltonian for the system can be written as

    where

    whereas ?p=ωp ?ω21, ?c=ωc ?ω32, ?2=?p+?cis the two-photon detuning andσiαβ=|α﹥ii﹤β|is the transition operator for atomiat positionri.The equations of motion can then be calculated using the Hamiltonian(Eq.(6))as

    where Γ2is the atomic decay rate whereasγ12,γ23, andγ13are dephasing rates.We know that the Rydberg state has longer life time so thatγ12≈γ23?γ13.In Eq.(8),S(rrr)represents the total vdW induced shift of the Rydberg state|3﹥and can be written as

    Now the steady state solution of Eq.(8)as

    We follow the same approach as discussed previously[19]and calculate the population of the Rydberg state without considering the vdW shiftS(rrr)as

    The population of the state|3﹥can be calculated by consideringγ31?γ21and ?p <γ21as

    Further, we study the vdW shift when an atom is in the Rydberg state|3﹥and makes a shift ?(R)for other atom positioned at a distanceR.Due to vdW interaction of an excited Rydberg atom all the other atoms cannot come to the excited Rydberg state in a small volumeVSAand is called Rydberg blockade or super atom.[13]In each blockade there are many atoms and can be defined asnSA=ρ(r)VSA, whereρ(rrr)represents the atomic density.It should be noted that there is only one Rydberg excited atom in each blockade.The atomic medium then form a collection of blockades and the number of blockades in volumeVcan be defined asNSA=ρSAV.Now the total vdW shift can be represented at any positionrrras

    In the right side of Eq.(13), the first term represents the excited blockade atrrrj=rrri.e.,ΣRR(rrr)→1,that creates a divergent vdW shift in a volume of a blockade and finally?(0)~= (1/VSA)∫VSA?rrr′d3rrr′ →∞.The second term in Eq.(13)represents the vdW induce shift and can be induced between the blockades and hence can be written as

    To find the expression fors(rrr), we use the mean field approximation[19]as

    herewin Eq.(14)represents the half width of population the in state|3﹥.In Eq.(14)we need to calculate the the value of ΣRR(rrr), so in the blockade the ground and single collective Rydberg excited state will take the form as under

    By considering a blockade in Rydberg state|G﹥, we can represent ΣRR(rrr)in the form as

    where

    The final expression for ΣRRcan be obtained by considering ΣGG+ΣRR=1 as

    The expression for optical susceptibility can take the final form as

    whereβ= 2NSA|μ21|2/?0.It should be noted that the optical susceptibility in Eq.(20)depends on the probe field Rabi frequency ?p.The probe field Rabi frequency is directly proportional to the incident electric probe fieldEm(z,y)as shown in Eq.(1).This clearly shows that the transmission Eq.(4)depends on the incident electric field via Rabi frequency ?p.The optical susceptibility depends onnSA, which clearly shows the blockade picture.It means that the blockade effect can change the optical susceptibility as depicted in Eq.(20).

    3 Results and Discussion

    Earlier, EIT has been realized in Rydberg atomic medium experimentally.[18,42?44]In an experiment,[18]the transmission spectrum of probe field has been studied in a medium having Rydberg states.It has been observed that the transmission spectrum of probe field decreases with increasing the intensity of the probe field and vice versa.In the experiment,[18]the authors have no clear evidence about the reduction of transmission of probe field via increasing the intensity of the probe field.Later, a theoretical model[19]has been developed and explained the reduction of probe field via increasing the intensity of probe field.The theoretical model was based on the blockade mechanism where each blockade has only one Rydberg excitation.In these investigations,[18?19]a coherent light beam has been used and investigated the transmission spectrum of probe light field.In the following, we use the same atomic medium as used earlier[18?19]and try to investigate the transmission spectrum and GHS in the transmission probe field using PCL field.

    Fig.2 (Color online)The transmission|T|2 versus probe field detuning ?p, the parameters are γ= 1MHz, ?c=7γ, γ21=3γ, γ31=0.01γ, m=2, and β=10γ.

    In order to study the effect of PCL field on the transmission spectrum and GHS in the transmitted probe light field, first we discuss about the role of factorq.Here,qplays an important character because for a coherent source of lightq ≥1 whereas for a PCLq <1.Earlier, the GHS and diffraction grating have been studied using a PCL field and investigated the influence of spatial coherenceqand beam width on the magnitude of the GHS and intensity of the diffraction grating.[39?41]We expect similar behavior of the spatial coherenceqand beam width on the transmission spectrum of probe field in the Rydberg atomic medium.We use Eq.(3),and plot the transmission spectrum of the probe field versus probe field detuning ?pfor two values of spatial coherenceqas shown in Fig.2.The plots show that the transmission spectrum influenced by the variation of the spatial coherenceq.For a coherent light i.e., whenq= 1, the transmission spectrum of probe field is shown in Fig.2(a).By decreasing the value of spatial coherenceqfrom 1 to 0.002, the light should be treated as PCL.In Fig.2(b), the transmission spectrum is shown for PCL in which the transparency reaches to its maximum value.It is also seen that the peak of transmission spectrum slightly shifted from the resonance condition.In comparison of Figs.2(a)and 2(b),the transparency peak increases for PCL as compared to coherent light.Clearly, the increase of transparency peak via PCL leads to increase the EIT.

    Fig.3 (Color online)The transmission|T|2 versus probe field detuning ?p, the other parameters remain the same as in Fig.2.

    The beam width of PCL also plays an important role when a probe field is propagating through a medium.[39?41]In these investigations,[39?41]large magnitude of the GHS and intensity of diffraction grating have been revealed for small beam width and vice versa.Therefore, here we are interested to investigate the influence of beam width on the transparency peak of probe light field.We choose the spatial coherenceq= 0.002 and investigate the transmission spectrum for different values of beam width of PCL.We plot the transmission of probe field versus probe field detuning as shown in Fig.3.In Fig.3(a), we show the transmission spectrum of probe field by considering the beam width of PCLws= 90λp.The transmission peak of probe field decreases in comparison of Fig.2(b)where we consideredq= 0.002 andws=80λp.This shows that by increasing the beam width of PCL field,the transmission peak decreases.For further increase of the beam width of PCL,the transmission peak decreases further as depicted in Fig.3(b).

    Besides,the transmission spectrum of probe field,next we study the influence of PCL field on the GHS in the TL.We use Eq.(5)and investigate the influence of spatial coherence and beam width on the amplitude of the GHS in the transmitted beam.By considering a large width of i.e.,ws= 80λpof PCL and probe field detuing ?p= 1γ,we plot the GHS in the TL versus incident angleθfor two values of spatial coherenceqas shown in Fig.4.The plot in Fig.4(a)shows that the GHS in the TL is positive as well as negative at different incident angleθfor a coherent light i.e.,q=1.It should be noted that the transmission spectrum in Fig.2(a)and the GHS in the TL in Fig.4(a)are shown for coherent light field and both figures.have the same parameters.Next,we consider a PCL as used for the transmission spectrum in Fig.2(b)and plot the GHS in the TL versus incident angleθby considering ?p=1γas shown in Fig.4(b).The plot shows that the magnitude of the GHS in the TL increases for PCL field.In comparison of Figs.2(b)and 4(b), we conclude that for high transmission of probe field, the magnitude of the GHS in the TL increases.

    Fig.4 (Color online)The GHS St/λp versus incident angle θ for ?p=1γ, the other parameters remain the same as in Fig.2.

    To study the influence of beam width of PCL on the GHS in the TL,we choose the spatial coherenceq=0.002 and vary the beam width.In the previous section, we investigated giant negative and positive shifts in the TL by consideringws= 80λpandq= 0.002 as shown in Fig.4(b).Now we increase the beam width fromws= 80λpto 90λpand remain unchanged all the other parameters and plot again the GHS in the TL versus incident angleθas depicted in Fig.5(a).The plot shows that the magnitude of the GHS decreases with increasing the beam width of PCL.Similar reduction of transparency peak is also investigated in Fig.3(a)for the same parameters.Similarly, for further increase of the beam width of PCL, the magnitude of the GHS decreases further as shown in Fig.5(b).

    Fig.5 (Color online)The GHS St/λp versus incident angle θ for ?p=1γ, the other parameters remain the same as in Fig.2.

    The influence of different modes on the GHS has been studied earlier,[36]in the following we study the effect of different modes of PCL on the transmission spectrum and magnitude of the GHS in the transmitted light.For incident angleθ= 0 andq= 0.002, we plot the transmission of probe field versus mode indexmas depicted in Fig.6(a).The plot shows that the transmission of probe field increases to its maximum valuem=10 and then decreases for further increasing the number of modes.Similarly, by consideringθ= 0.71 rad andq= 0.002, we plot the GHS versus mode indexmof PCL as shown in Fig.6(b).The plot shows that the magnitude of the negative GHS in the transmitted becomes maximum form=2 and decreasing for further increasing the mode indexm.

    Fig.6 (Color online)The transmission and GHS versus mode index m for ?p=1γ, the other parameters remain the same as in Fig.2.

    4 Summary

    In summary, we considered a cold atomic medium of cascade configuration having Rydberg excitation.A PCL beam is incident on a medium having lengthLand making an angleθwithz-axis.We studied the transmission of probe field and GHS in the TL under the influence of spatial coherence and beam width of PCL field.Maximum transmission of probe field is achieved for PCL field while low transmission for coherent light.Similarly, giant GHS in the TL is revealed for PCL field while investigated GHS with small magnitude for coherent light.The influence of beam width of PCL on the transmission spectrum and GHS in the TL is also studied.Maximum transmission of probe field and giant GHS in the TL are investigated for small beam width of PCL and vice versa.

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