Abstract
We present dichroic x-ray lensless magnetic imaging by Fourier transform holography with an extended reference scheme via a modified uniformly redundant array (mURA). Holographic images of magnetic domains simultaneously generated by a single pinhole reference as well as by a mURA reference are compared with respect to the signal-to-noise ratio (SNR) as a function of exposure time. We apply this approach for spectro-holographic imaging of ferromagnetic domain patterns in Co/Pt multilayer films. Soft x-rays with wavelengths of 1.59 nm (Co L3 absorption edge) and 20.8 nm (Co M2,3 absorption edges) are used for image formation and to generate contrast via x-ray magnetic circular dichroism. For a given exposure time, the mURA-based holography allows to decouple the reconstruction SNR from the spatial resolution. For 1.59 nm wavelength, the reconstruction via the extended reference scheme shows no significant loss of spatial resolution compared to the single pinhole reference. In contrast, at 20.8 nm wavelength the single pinhole reveals some very intricate features which are lost in the image generated by the mURA, although overall a high-quality image is generated. The SNR-advantage of the mURA scheme is most notable when the hologram has to be encoded with few photons, while errors associated with the increased complexity of the reconstruction process reduce the advantage for high-photon-number experiments.
Highlights
Fourier transform holography (FTH) is an imaging technique that is based on the interference of the light scattered by an object with a spherical reference wave originating in or close to the object plane [1]
We are able to image ferromagnetic domain patterns at both the L3 and M2,3 absorption edges of Co and directly compare them with a respective hologram recorded under identical conditions via a single pinhole reference
We analyze the gain in signal-to-noise in the reconstructed real-space magnetization map obtained by using the modified uniformly redundant array (mURA) versus single pinhole reference as a function of incident photon dose and comparing single helicity and helicity difference holograms
Summary
Fourier transform holography (FTH) is an imaging technique that is based on the interference of the light scattered by an object with a spherical reference wave originating in or close to the object plane [1]. With the appreciable coherent photon flux from 3rd generation synchrotrons as well as the increased availability of free-electron x-ray lasers on one hand and. For laboratory sources, extending the wavelength range towards such short wavelengths with coherent photon fluxes suitable for high-resolution imaging is still a formidable challenge, but progress in recent years has been fast [9,10,11,12,13,14]. While FTH with x-rays has become routine at 3rd generation synchrotron sources [1, 15,16,17,18,19,20], when pushing the resolution below the 10 nm region, investigating very weak contrast objects, imaging with extreme temporal resolution or even via a single femtosecond flash exposure at short wavelengths, the signal-to-noise ratio (SNR) achievable in the hologram at high momentum transfer remains a challenge
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