1 Introduction
The study of open quantum systems describes the possible interactions of a system showing quantum properties with any kind of external perturbation. They can be distinguished between two major categories: a first group in which the characteristics contained in the quantum system are being irreversibly lost or degraded (Markovian systems), and a second in which information is transmitted or exchanged between the quantum system and the environment (non-Markovian systems) (Breuer et al. Reference Breuer, Laine, Piilo and Vacchini2016).
Matter–wave experiments performed in vacuum allow the investigation of the first category, for example, by observing the loss of contrast of the interferometric pattern while degrading the vacuum level of the experimental set-up, as was demonstrated in Hornberger et al. (Reference Hornberger, Uttenthaler, Brezger, Hackermüller, Arndt and Zeilinger2003) and Schütz et al. (Reference Schütz, Rembold, Pooch, Chang and Stibor2015). Here, the quantum phase information is lost and the interference patterns are irreversibly washed away by a series of scatterings of the particles with the residual gas.
In the second category, we can find the quantum systems that interact coherently with other physical systems possessing well-defined phase properties, thereby making possible the exchange of the information between the two systems. They are based on the fact that the interaction is non-dissipative in its essence. Under these conditions, the change in visibility of an interferometric pattern might show the effect of ‘quantum revival’: an oscillatory behaviour of the visibility as the interaction parameter between the two systems monotonically increases. This is, for instance, the case when an interferometric pattern is suitably made to interfere with a laser system. Such revivals can also be found by investigating other aspects such as coherence, entanglement and quantum correlations (Maniscalco, Olivares & Paris Reference Maniscalco, Olivares and Paris2007; Vasile et al. Reference Vasile, Giorda, Olivares, Paris and Maniscalco2010; Benatti, Floreanini & Olivares Reference Benatti, Floreanini and Olivares2012; Cialdi et al. Reference Cialdi, Benedetti, Tamascelli, Olivares, Paris and Vacchini2019).
Focusing on matter–wave interference experiments in the non-Markovian case, this condition has been studied and observed in Chapman et al. (Reference Chapman, Hammond, Lenef, Schmiedmayer, Rubenstein, Smith and Pritchard1995), where an atom interferometer has been subjected to the perturbation induced by single photons. Our study here differs from Chapman et al. (Reference Chapman, Hammond, Lenef, Schmiedmayer, Rubenstein, Smith and Pritchard1995) in two fundamental aspects: first of all, we consider the quantum revival effect between an antiparticle (as opposed to a particle) and a coherent electromagnetic field. Secondly, we discuss an interaction case where the massive system (and not the photon) is in the single-particle mode.
In essence, we pave the way for studying the revival effect in a single-particle mode, never studied before (by using antiparticles).
The basis and inspiration for this work is the first detection of antiparticle (positron) interference in our QUPLAS (QUantum interferometry and gravitation with Positrons and LASers) experiment (Sala et al. Reference Sala, Ariga, Ereditato, Ferragut, Giammarchi, Leone, Pistillo and Scampoli2019). This interference, obtained with a Talbot–Lau configuration (Sala et al. Reference Sala, Castelli, Giammarchi, Siccardi and Olivares2015; Sala, Giammarchi & Olivares Reference Sala, Giammarchi and Olivares2016), has been obtained in single-particle mode, similarly to the historical experiment with electrons performed by Merli, Missiroli & Pozzi (Reference Merli, Missiroli and Pozzi1976).
2 The strategy
The first stage of the QUPLAS experiment featured a positron beam coupled with a Talbot–Lau interferometer and a high-resolution emulsion detector (Anzi et al. Reference Anzi, Ariga, Ereditato, Ferragut, Giammarchi, Maero, Pistillo, Romé, Scampoli and Toso2020; Ariga et al. Reference Ariga, Cialdi, Costantini, Ereditato, Ferragut, Giammarchi, Leone, Maero, Miramonti and Pistillo2020). In the experimental configuration, the two gratings have different periods ($d_1=1.2\,\mathrm {\mu }{\rm m}$ and $d_2=1\,\mathrm {\mu }{\rm m}$, respectively) so that the configuration acts as a magnifier of the diffraction pattern. The distance $L_1$ between the two gratings (see figure 1) is set to $L_1=d_1 d_2 / \lambda$ (Sala et al. Reference Sala, Ariga, Ereditato, Ferragut, Giammarchi, Leone, Pistillo and Scampoli2019), where $\lambda = h/mv$ is the De Broglie wavelength, with $m$ and $v$ the positron mass and velocity, respectively, and $h$ Planck's constant. In order to obtain the maximum contrast on the detector, this is located at a distance $L_2$ from the second grating given by the relation $L_2= d_2 L_1/(d_1-d_2)$.
The experiment is powered by a 50 mCi $^{22}$Na positron source. After a few preparation steps, an almost monochromatic (energy spread of a few eV) positron beam with energies tuneable in the range 10–20 keV is obtained. At these velocities, the particles pass through the interferometer in a fraction of $\mathrm {\mu }$s. Taking into account all the losses due to solid angle, moderation and other processes, the flux turns out to be $\simeq 10^4\,{\rm particles}\,{\rm s}^{-1}$. Taking into account the paucity of this beam and the fact that the radioactive material is an incoherent fermionic source, the experiment is definitely in the single-particle regime.
The present configuration, featuring two silicon nitride material gratings, will be supplemented by a microwave cavity, located after the second grating, as shown in figure 1, providing a standing ($\sim$10 GHz) electromagnetic field. Therefore, the positrons crossing the second grating will interact with the photons in the microwave cavity. This interaction can be described by a Hamiltonian of the form (Friedman et al. Reference Friedman, Gover, Kurizki, Ruschin and Yariv1988; Henke et al. Reference Henke, Raja, Feist, Huang, Arend, Yang, Kappert, Wang, Möller and Pan2021)
where $a$ and $a^{\dagger}$ are the boson field annihilation and creation operators, $[a,a^{\dagger} ] = 1$, $g$ is a coupling constant and $b$ the positron-energy ladder operator, reducing its energy by the energy of one microwave photon and changing its linear momentum. This interaction produces an entanglement between positrons and photons, having the form
where $n$ is the number of exchanged photons (having frequency $\omega$) and $c_n$ are amplitudes. Different effects are then obtained as a function of the power in the microwave cavity, which is related to the number of photons in the expansion. In the case of a small coupling constant, $| \psi _e, \psi _\gamma \rangle$ is dominated by the effect of one or two photons
In the presence of a macroscopic, monochromatic microwave field, namely, a coherent state of the radiation field, we can substitute for $\hat {a}$ in (2.1) the complex amplitude $\alpha$ of the microwave field, that reduces to a momentum-displacement operation, in analogy with the same kind of operation in quantum optics (Olivares Reference Olivares2021).
In principle, one should solve the Schrödinger equation with the above Hamiltonian for the proposed experimental configuration. In order to simplify the problem we have developed two complementary approaches:
(i) the two-slit model;
(ii) the Gaussian–Schell model (GSM).
In the two-slit model, the grating structure is geometrically simplified down to the simplest Young-like configuration, taken to grasp the essence of the phenomenon. The idea is to model a single positron passing through the interferometer and interacting with the microwave cavity. On the other hand, the GSM is an analytical model used for the statistical treatment of partially coherent beams. Both models will be shown to give consistent results.
3 The two-slit model
The two-slit model assumes that the essence of the phenomenon is equivalent to considering two neighbouring slits belonging to the second grating, as shown in figure 2. We assume that a non-relativistic positron is propagating along the $z$ direction, while the grating slits are parallel to the $x$ direction (orthogonal to the $(y,z)$ plane shown in figure 2); under these conditions, interference will show up along the $y$ axis. The microwave cavity is modelled as a rectangular wave guide with length $w$ and transverse dimensions $a$ and $b$. Considering only the fundamental mode TE$_{10}$ of the wave guide, the stationary field is characterized by a longitudinal wavenumber
where $\nu _0$ is the frequency of the microwave field, and $\nu _c = c/2a$ the cutoff frequency of the TE$_{10}$ mode.
The vector potential of the confined microwave field in the cavity is given by
where $E_0$ is the amplitude of the electric field, $\omega =2{\rm \pi} \nu _0$ and $\varphi$ is a phase. The origin of the coordinates is placed at the centre of the opening for the passage of positrons into the microwave cavity. Assuming the diameter of this opening is much smaller than the linear dimensions of the microwave cavity and of the wavelength of the TE$_{10}$ mode inside the cavity, the potential (3.2) can be simplified as
The amplitude of the wave electric field in the wave guide can be written in terms of the time-averaged (over a wave period) peak power $P$ by means of the relation
where $\eta = 1/\epsilon _0 c \sqrt {1-(\nu _c/\nu _0)^2}$ is the wave impedance.
Neglecting the term proportional to the square of the vector potential (low amplitude wave electric field), the Hamiltonian of the interaction between the particle and the field reads
where $e$ is the positron charge, and $p_z \simeq m v$ (neglecting the transverse velocity components of the particle).
The effect due to two neighbouring slits is summarized by an overall shift
where $\tau \simeq w/v$ is the crossing time of the positron in the wave field, and $H_1$ and $H_2$ denote the interaction Hamiltonian relevant to the passage of the particle through slits 1 and 2, respectively, separated by a distance $d_2$ (i.e. the period of the second grating).
For a uniform random distribution of the phase $\varphi$, the degree of decoherence introduced by the stationary field can be quantified by means of
The function $D$ is real and coincides with the visibility of the interference pattern. An example of the dependence of $D$ on microwave power is given in figure 3.
4 The Gaussian–Schell model
The same physical problem has been addressed by means of a simulation that makes use of an analytical description of the beam, namely the GSM (McMorran & Cronin Reference McMorran and Cronin2008).
In the GSM, the partial coherence and wavefront curvature of a beam are taken into account by using a series of parameters describing the non-ideality of both the beam and of the related grating system. This approach has a great versatility, and can describe a variety of interferometric situations in different regimes (Talbot–Lau, Fraunhofer, Mach–Zehnder$\ldots$).
The model describes a partially coherent beam as a statistical distribution of Gaussian modes, characterized by its initial width, coherence length and wavefront curvature. In the simulation, we have assumed that only the transverse part contributes to the coherence length; this is due to the good monochromaticity of the QUPLAS positron beam (good longitudinal coherence) (Ariga et al. Reference Ariga, Cialdi, Costantini, Ereditato, Ferragut, Giammarchi, Leone, Maero, Miramonti and Pistillo2020). The ingredients used in the GSM calculation are:
(i) The mutual intensity function.
(ii) Its propagation in free space.
(iii) Its modification due to the effect of the gratings and microwave cavity.
The mutual intensity function is used in partially coherent optics, where it is considered that a beam has some momentum distribution in the direction transverse to propagation. It is defined by
where $\varPhi$ is a field, $\boldsymbol {x}_a, \boldsymbol {x}_b$ are coordinates orthogonal to the $z$ propagation direction of the beam and the angular brackets denote a time average over the statistical fluctuations of the field. This quantity describes both the spatial coherence of the beam and its intensity, as given by the relation
Once this function is given at $z=0$, the beam propagation in space can be described by means of the Van Cittert–Zernike theorem, that links the mutual intensity function $J$ to the Fourier transform of the intensity of a partially incoherent source, enabling us to devise a free propagation law for $J$
where $\boldsymbol {x} = (\boldsymbol {x}_a + \boldsymbol {x}_b)/2$ and $\Delta \boldsymbol {x} = \boldsymbol {x}_b - \boldsymbol {x}_a$. This law gives the mutual intensity function $J$ at some $z$, given its form at $z=0$ for the case of free propagation.
The structure of the initial mutual intensity function is specified as
where $w_0$ is the beam opening (width), $l_0$ the transverse coherence length and $r_0$ the radius of curvature of the wavefront. In the free propagation of the beam from $z_0=0$ to a generic position $z$, the mutual intensity function $J$ retains the Gaussian structure, with the values of the parameters evolved as
Concerning the initial beam parameters, they were experimentally determined by a series of runs in the standard QUPLAS configuration (without the microwave cavity) as $l_0 = 0.65$ nm and $w_0 = 2.4$ mm, neglecting the effect of the curvature radius (Sala Reference Sala2018).
The action of a grating is represented by means of its transmission function $\mu$, so that the mutual intensity function at the $z$-coordinate of the grating is changed as
In order to describe material gratings realized as open slits in a substrate, $\mu$ is simply assumed in each period $d$ as 1 in an interval of width $fd$ (open slit), and 0 in a following interval of width $(1-f)d$ (substrate), where $f$ is the transparency of the grating.
After an initial phase of free propagation, the operation (4.8) is performed a first time in the position of the first grating (period and transparency $d_1$ and $f_1$, respectively), followed by a new phase of free propagation for the modified $J$ up to the second grating. Then the mutual intensity function is changed again on the basis of (4.8) in the position of the second grating (period and transparency $d_2$ and $f_2$, respectively).
The insertion of the microwave cavity changes the propagation after the second grating. Its effect is modelled again using (4.8) with a transmission function $\mu = \exp (\tilde {\varPhi })$. Using the same approximations adopted in the two-slit model
The intensity at the $z$-coordinate of the detector is finally computed after a final phase of free propagation, and averaging over the phase $\varphi$. The resulting visibility of the interferometric pattern is shown for fixed values of the relevant parameters and compared with the result of the two-slit model in figure 3.
5 Conclusion
We have proposed and analysed the non-Markovian interaction between an antiparticle and a carefully prepared electromagnetic microwave field. The results indicate the feasibility of the experiment, currently being planned as an upgrade of the QUPLAS set-up.
This experiment can shed light on the interaction and the mutual exchange of coherence between a quantum system and an electromagnetic field, in particular, in the unexplored regime where the field interacts with a single antiparticle. We believe that such a proposal and the related experiment is an important step to improving the fundamental aspect of quantum mechanics beyond the ‘matter’ realm, but also to foster new experimental techniques that can be used in other anti-matter related experiments.
Acknowledgements
Editor F. Califano thanks the referees for their advice in evaluating this article.
Declaration of interests
The authors report no conflict of interest.