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1.IntroductionThe limit of resolution is generally expressed by Rayleigh's criterion of resolution given by Eq. 1[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{equation} {d_{\min}} = \alpha \frac{\lambda }{\mathrm{NA_{MO}}}, \end{equation} \end{document}On the other hand, coherent imaging is an attractive research tool in many fields of biological research.3 Techniques such as digital holographic microscopy (DHM) have the capability of imaging amplitude and quantitative phase simultaneously.4 Consequently, the method is marker-free, noninvasive regarding the light intensity, and only camera acquisition rate limited. Many attempts have been made to overcome a shortage in resolution power of coherent imaging systems. The general approach consists in exploiting unused degrees of freedom.5 Following that idea, interference of spherical waves can be used to create phase vortex arrays.6, 7 Recently, the significance of such phase singularities for resolution has been demonstrated.8 Following, it has been outlined how to fully exploit bandpass information content and how to directly improve coherent imaging system resolving power.9 The purpose of this paper is to investigate the principal lateral and axial resolution limits which can be related to the occurrence of asymmetric singularities in phase. Based on this observation, we elaborate concepts for coherent resolution beneath Abbe's limit [⩽λ/(2NAMO)] with high-NAMO. 2.Asymmetric Phase SingularitiesThe destructive interference between waves emitted from point-scatterers results in phase singularities. Such discontinuities occur at spatial positions where the spherical waves emitted from each hole are out of phase. As reported earlier,8 the orientation angle θ of those lines of singularities varies systematically with the point-scatters’ pitch η. Our experimental realization of point-scatterers is depicted in Fig. 1a, whereas Fig. 1b shows schematically their phase response in an image plane. A total of four destructive interferences are possible for the two pairs of rings. The characteristic spacing s between two out of phase circles, r 1 and r 2, i.e., with phase difference ΔΦ = π, can be calculated by Eq. 2[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{equation} s=\frac{\Delta \Phi }{k_\mathrm{max}}=\frac{\pi }{(2\pi /\lambda)\mathrm{NA_{MO}}}=\frac{\lambda }{2\mathrm{NA_{MO}}}, \end{equation} \end{document}Eq. 3[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{equation} s_\pm =s\pm \Delta {s}=s({1}\pm \mathrm{NA_{MO}}\Delta \phi {/}\pi), \end{equation} \end{document}Eq. 4[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{eqnarray} \eta (\theta _\pm, r, s_\pm) &=& \Big \lbrace 2 r^2+2 r s_\pm +s_\pm ^2 -\big[4 r^2 (r+s_\pm)^2 \nonumber\\ &&-s_\pm ^2 (2r+s_\pm)^2 \cot ^2\theta _\pm \big]^{1/2}\Big \rbrace ^{1/2}, \end{eqnarray} \end{document}Eq. 5[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{equation} \eta (\theta _+,r,s_+) \stackrel{!}{=} \eta (\theta _-,r,s_-). \end{equation} \end{document}2.1.Axial ResolutionA longitudinal displacement Δz of one of the point-scatterers results in an offset phase difference Eq. 6[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{equation} \Delta \phi _\mathrm{long} = \frac{2\pi {n_m}\Delta {z}}{\lambda }, \end{equation} \end{document}Eq. 7[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{eqnarray} && \theta _\pm [\eta, r, s_\pm ]\nonumber\\ && \quad = \text{arctan} \big(s_\pm (2 r+s_\pm)\left\lbrace (s_\pm ^2-\eta ^2) \left[\eta ^2-(2 r+s_\pm)^2\right]\right\rbrace ^{-1/2}\big).\nonumber\\ \end{eqnarray} \end{document}Typically, that can be related with an axial precision of Δz ≈ 25 nm at λ = 532 nm, η = 400 nm and NAMO ≈ 1. Through several ring measurements, one can obtain such a statistical accuracy or better. On the other side, practical considerations, like discretization concerns or asymmetric aberrations,8 might limit axial resolution. 2.2.Lateral ResolutionGiven that θ can maximally reach π/2, Eq. 4 converges to Eq. 8[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{equation} \lim _{\theta \rightarrow \pi /2}\eta = s_\pm, \end{equation} \end{document}Eq. 9[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{equation} {d_{\rm min}^{\pm }} =\mathrm{min}\left[\eta \right]=\mathrm{min}\left[\frac{ \lambda }{2}\Big (\frac{1}{\mathrm{NA_{MO}}}\pm \frac{\Delta \phi }{\pi }\Big)\right]. \end{equation} \end{document}Eventually Eq. 9 is based on the assumption that Δϕ itself can be created without any limitation on its lateral extension. If, however, Δϕ is created by tilt illumination as suggested by Fig. 3, the dephasing is a function of η as further discussed in Sec. 3. 3.ExperimentFor the proof of principle, we use a test target consisting of a thin opaque aluminum film (thickness = 100 nm) on a conventional coverslip.12, 13 Nanometric apertures (⊘nominal = 80 nm) are drilled by focused ion beam (FIB) milling in the coating and are placed at very close pitches η. The fabricated pitch is controlled and measured by scanning electron microscopy (SEM), as shown in Fig. 1a. The different double hole series serve as experimental test targets. For phase imaging, a DHM setup in transmission configuration (cf. Fig. 3) is used. The light source is a neodymium-doped yttrium aluminium–garnet laser (Nd:YAG) at wavelength λ = 532 nm. The DHM setup is equipped with a microscope objective, 63 × NAMO = 0.93 (in air) in combination with an additional relay magnification to reach a lateral sampling δx of 80 nm. The condenser lens’ numerical aperture, called NAcond, is 0.25. It is difficult to experimentally realize exact and small axial displacements Δz of one hole relative to another. Instead, we present a proof-of-principle measurement of the impact of Δϕ on lateral resolution. The phase difference Δϕ is created by a wedge prism which is put in imaging condition with respect to the sample by a 4-f system, shown in Fig. 3. The incident angle α can maximally reach the steepest angle allowed by NAcond used to excite the point-scatters. Hence, the phase difference Eq. 10[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{equation} \Delta \phi _\mathrm{lat}=\frac{2\pi {n_m}\eta \mathrm{sin}\alpha }{\lambda }\mathrm{cos}\beta, \end{equation} \end{document}Eq. 11[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{equation} s_{\pm }=\frac{\lambda }{2\mathrm{NA_{MO}}}\pm \eta \mathrm{NA_{cond}\cos \beta }. \end{equation} \end{document}Eq. 12[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{equation} {d_{\min}^{+}}=\mathrm{min}\left[\eta \right]=\frac{\lambda }{2\mathrm{NA_{MO}}\left[1+\mathrm{NA_{cond}}\right]}. \end{equation} \end{document}Eq. 13[TeX:] \documentclass[12pt]{minimal}\begin{document} \begin{equation} \lim _{\mathrm{NA_{cond}}\rightarrow \mathrm{max}}{\lim _{\mathrm{NA_{MO}}\rightarrow \mathrm{max}}} {d_{\min}^{+}} \approx \frac{\lambda }{7.2}, \end{equation} \end{document}4.ResultsIn Figs. 4a, 4c, 4k, and Figs. 4g, 4i, 4k the phase singularities’ behavior for tuning β is demonstrated with different pitches η. It can be seen that singularities’ orientations can be indeed tuned by introducing a phase difference Δϕ that is controlled by the wedge prism's orientation β, as defined in Fig. 3. The phase singularities are symmetrically oriented for a perpendicular holes’ excitation (β = π/2), shown in Fig. 4c for η = 400 nm and Fig. 4i for η = 300 nm. Both images show the phase map of distances η well beneath the Rayleigh resolution limit of [TeX:] \documentclass[12pt]{minimal}\begin{document}${d_{\min}^{\rm Rayleigh}}\approx 470$\end{document} nm. The pitch of image Fig. 4c is about Abbe's resolution limit of [TeX:] \documentclass[12pt]{minimal}\begin{document}${d_{\min}^{\rm Abbe}}\approx 300$\end{document} nm. Thus, four singularities are observable in Fig. 4c, while they seem to merge to two broadened singularities in Fig. 4i. By detuning β, Δϕ ≠ 0 can be controlled and the phase singularities become asymmetrically oriented. In the case of η = 400 nm, the two singularities merge on one side while opening up further on the opposed side. This results in a total of three singularities in Figs. 4a, 4e. In the case of η = 300 nm, an originally merged singularity opens up again and consequently results in three singularities in Figs. 4g, 4k. The importance of the described behavior can be well observed in their spectra, depicted in Figs. 4b, 4d, 4f, and Figs. 4h, 4j, 4l. The Fourier-transform leads to a mixing up of modulus and phase of the complex image. Thus, the real space phase singularities are seen as minimum transmittances in the amplitude k-space (wavenumber). Figures 4d, 4j visualize the significance of [TeX:] \documentclass[12pt]{minimal}\begin{document}${d_{\min}^{\rm Rayleigh}}$\end{document} and [TeX:] \documentclass[12pt]{minimal}\begin{document}${d_{\min}^{\rm Abbe}}$\end{document} . At Abbe's resolution limit of η = 300 nm in Fig. 4j, the minimal transmittances reach the bandpass's edges, which corresponds to a wavenumber content of k ≈ 2(2π/λ). The transmittances minima shift asymmetrically to different frequencies as β is detuned, yielding for Δϕ ≠ 0. As observed in Fig. 4, their positions shift on one spectral side to lower and on the other spectral side to higher wavenumbers k x. In this manner, higher frequencies that are originally not allowed by the bandpass can be accessed. Eventually, it gives rise to resolution beneath Abbe's limit. The maximal shift of the transmittances minima in Fig. 4 corresponds to the largest angle θ of the phase singularities. The comparisons of real-space with its corresponding spectra reveal that θ can be more precisely assessed in k-space. For instance, one can see that the three singularities in phase image Fig. 4a correspond actually to four singularities in k-space. In real space, this behavior is barely observable due to broadening effects.10, 11 For the following analysis, the angle θ is directly measured from the spectra in Fig. 4 and results are visualized in Fig. 5. It compares the experimental values of θ directly to the theory of Eqs. 7, 11. Nonzero phase shifts, i.e., β ≠ π/2, lead to a splitting up of singularities’ orientation θ±. In Fig. 5a, angles θ± never exceeds the maximal orientation of θ = π/2. Contrarily, in the case of Fig. 5b, the saturation point is already reached by little detuning of β. It features only three singularities over a large β-range. The experimentally observed behavior follows the theoretical prediction within the angular precision, both illustrated in Fig. 5. 5.DiscussionThe test target of Fig. 1a has been especially designed to analyze the resolving power of phase imaging. It allows direct proof-of-principle measurements and demonstrates the practical role of coherent cross-talk in phase imaging. In a more general view, any nontransparent object could be thought to be composed of a three-dimensional distribution of scatterers, thus resulting in coherent cross-talk. Since the presented method is based on interferometric phase imaging, the described effects are generally less dependent on a number of photons.14 Even in the case of phase objects, the occurrence of phase singularities has been reported.6 The observation of phase singularities serves two purposes. On the one hand, it offers a direct method of measuring lateral and axial distance differences between point sources to a higher accuracy than intensity imaging alone. On the other hand, it allows to study the information content of any coherent imaging systems bandpass. In Sec. 4, k-space information content is demonstrated to be in accordance with Abbe's diffraction limit in configuration of Fig. 6a. We propose the technique of complex deconvolution to fully exploit bandpass limited information content.9 To further increase bandpass’ information content beyond Abbe's limitation, phase shifts Δϕ can be introduced as summarized in Fig. 6b and Eq. 9. Experimentally, such conditions can be achieved for any sample by illumination beam scanning15 or sample rotation.16 Consequently, information content is increased and may be exploited by synthetic bandpass aperture17 combined with complex deconvolution.16 In this configuration, Eq. 10 teaches that resolution is limited by wavelength λ, tilting angle α, and scatterer's distance η. However, following the idea of tuning Δϕ, Fig. 6c suggests how to overcome those limitations. We propose a tunable π-step phase scanning method, which results in maximal asymmetric singularity states. As known from STED or PALM-STORM, beam modulation patterns such as phase plates18 or spatial light modulation19 can be used to create first-order Bessel beams with line-singularities. Alternatively, also a “doughnut” mode beam intrinsically offers a steep π-step.20 In this manner, the illumination beam itself can be used to scan through phase states and switch them dependently of sample's optical properties. The technique's resolution given by Eq. 9 should be, in principle, only limited by phase gradient's width γ, as seen in Fig. 6c. If combined with DHM detection, a marker-free resolution well beyond λ/7.2 could be accessed, resulting in a new field of phase imaging applications for biological research.21 6.Concluding RemarksBased on fundamental geometry and elemental physical considerations, resolution theory is extended for coherent imaging systems. Scatterer's relative axial displacement Δz leads to dephased signals. 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