Abstract
Recently, the diffractogram, that is, the Fourier transform of the intensity contrast induced by Fresnel free-space propagation of a given (exit) wave field, was investigated non-perturbatively in the phase-scaling factor S (controlling the strength of phase variation) for the special case of a Gaussian phase of width sqrt{{bf{w}}}. Surprisingly, an additional low-frequency zero σ* = σ*(S, F) >0 emerges critically at small Fresnel number F (σ proportional to square of 2D spatial frequency). Here, we study the S-scaling behavior of the entire diffractogram. We identify a valley of maximum S-scaling linearity in the F − σ plane corresponding to a nearly universal physical frequency ξml = (0:143 ± 0.001)w−1/2. Large values of F (near field) are shown to imply S-scaling linearity for low σ but nowhere else (overdamped non-oscillatory). In contrast, small F values (far field) entail distinct, sizable s-bands of good S-scaling linearity (damped oscillatory). These bands also occur in simulated diffractograms induced by a complex phase map (Lena). The transition from damped oscillatory to overdamped non-oscillatory diffractograms is shown to be a critical phenomenon for the Gaussian case. We also give evidence for the occurrence of this transition in an X-ray imaging experiment. Finally, we show that the extreme far-field limit generates a σ-universal diffractogram under certain requirements on the phase map: information on phase shape then is solely encoded in S-scaling behavior.
Highlights
The emergence of intensity contrast through free-space propagation of a phase modulated paraxial wave field[1,2] is exploited in many imaging modalities including neutron scattering, transmission electron microscopy, and X-ray phase-contrast imaging
The observation made in the last section that scale objects of a broad spectrum (SOBS)-phase shape information transmutes into S-scaling information in the extreme far-field limit can be generalized to those multi-scale objects of a broad spectrum (MOBS) phase maps φ{wi}, carrying spatial scales {wi}, for which the following condition holds: There exists a normalization N{wi} such that κli→m0N{−κ1wi}φ{κwi}(x) S=1 = δ(2)(x⊥)
In this work we have investigated the S-scaling properties of diffractograms induced by free-space propagation of wave fields subject to a Gaussian phase map of width w
Summary
The emergence of intensity contrast through free-space propagation of a phase modulated paraxial wave field[1,2] is exploited in many imaging modalities including neutron scattering, transmission electron microscopy, and X-ray phase-contrast imaging. We investigate the diffractograms induced by three different SOBS phase maps which become re-scaled Dirac delta functions for w → 0.
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