Large As sublattice distortion in sphalerite ZnSnAs2 thin films revealed by x-ray fluorescence holography

Hayashi, Kouichi; Uchitomi, Naotaka; Yamagami, Keitaro; Suzuki, Akiko; Yoshizawa, Hayato; Asubar, Joel T.; Happo, Naohisa; Hosokawa, Shinya

doi:10.1063/1.4945004

Cited by 42 publications

(24 citation statements)

References 34 publications

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“…In the ternary II‐IV‐V 2 semiconductors, XFH experiments have been performed on an epitaxial ZnSnAs 2 films grown on an InP substrate . The result shows that the local structure of ZnSnAs 2 layer has been explained by a sphalerite structure rather than a chalcopyrite structure …”

Section: Introductionmentioning

confidence: 99%

X‐Ray Fluorescence Holography Analysis of Local Structure in CuInSe₂ and CuGaSe₂

Shirakata

Happo

Hosokawa

2019

Physica Status Solidi (a)

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X‐ray fluorescence holography (XFH) is carried out using a synchrotron radiation on CuInSe2 and CuGaSe2 single crystals, which is powerful for the investigation of local atomic structure by three‐dimensional atom image. Incident X‐ray energies (9.7–12.7 keV) are used to excite the Cu Kα fluorescent X‐ray. Atom images are regenerated by Fourier transformation. In the cation plane in CuInSe2 (z = 0), the cation atom spots observed are the 2nd (In), 4th (Cu), 8th (Cu), and 10th (In) – nearest neighbor (NN) of the central Cu atom. For the anion plane (z = c/8) of CuInSe2, Se atoms spots, 1st and 3rd NN of Cu, are observed. Se atom spots are seen to deviate from the regular tetrahedral position due to the bond length difference between Cu‐Se bond and In‐Se bond. In the CuGaSe2 epitaxial layer (300 nm) grown on (100) GaAs, the cation plane exhibits clear atom spots of Cu and Ga atoms up to10th (Ga) NN of Cu. In the anion plane (z = c/8), only 1st NN Se atom spots are observed, and those of 3rd NN atom spots are not been observed. These results are discussed with relation to the perturbation acting on the Se atoms.

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Section: Introductionmentioning

confidence: 99%

X‐Ray Fluorescence Holography Analysis of Local Structure in CuInSe₂ and CuGaSe₂

Shirakata

Happo

Hosokawa

2019

Physica Status Solidi (a)

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“…This means that no specific model of the atomic structure is necessary beforehand for the analysis of the XFH data, in contrast to e.g., XAFS, where a good model is usually required to analyze the experimental data. XFH can visualize the local structure in principle up to several nm (e.g., in Hayashi et al), thus representing a link between information derived from XAFS (usually only suitable to study nearest or next‐nearest neighbors) and XRD results (which only probes the average structure). In this work, we will present XFH measurements for the FeSe 0.4 Te 0.6 superconductor, which has a T C of 13.5 K .…”

Section: Introductionmentioning

confidence: 99%

Local Structure of FeSe_0.4Te_0.6 by Low‐Temperature X‐Ray Fluorescence Holography

Stellhorn

Ideguchi

Kawasaki

et al. 2018

Physica Status Solidi (b)

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We present low‐temperature X‐ray fluorescence holography experiments to investigate the atomic scale structure of the high‐temperature superconductor FeSe0.4Te0.6. The results present a direct investigation of the local structure around the Fe atoms. Very clear images of the structure are obtained by a sparse modeling approach to the experimental data using a L1‐regularized linear regression. The results are in good agreement with previous findings of XRD and XAFS experiments on the FeSe1−xTex system, but furthermore indicate large fluctuations in the Fe sub‐lattice. The findings also represent a starting point for further discussions on more curious features of the FeSe1−xTex structure.

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“…The advantages of the XFH technique are listed as follows: –3D atomic images can be obtained with no special models. –Local atomic structures can be evaluated around a specific element up to more than 15 neighboring atoms (see Figure d–f of Hayashi et al for a GaAs crystal). –No special limitations for impurities or low dimensional samples such as thin films. –Spatial fluctuations can be determined for each neighboring atoms. –Single phases are not necessary for the sample. …”

Section: Introductionmentioning

confidence: 99%

Applications of a L₁‐Regularized Linear Regression to X‐Ray Fluorescence Holography Data of Functional Materials

Hosokawa

Stellhorn

Hayashi

et al. 2018

Physica Status Solidi (b)

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To clarify atom‐resolved structural characterizations of materials, X‐ray fluorescence holography (XFH) technique is employed for drawing three‐dimensional (3D) atomic images around a specific element emitting fluorescent X‐rays. By taking the angle dependences of the fluorescent X‐ray intensity (hologram), 3D images of the surrounding atoms can be, in principle, obtained via simple Fourier transform‐like approaches with no special atomic models. In reality, however, an infinite number of the holograms with different incident X‐ray energies are necessary to reproduce the artifact‐less atomic images at the correct positions. Instead, here an inverse problem is applied using a sparse modeling approach of a L1‐regularized linear regression to solve such statistical problem of a small data size. The excellent results of this approach are presented on complex crystals of some functional materials, such as Mn doped Bi2Te3 topological insulator, Fe65Ni35 Invar alloy, and Fe chalcogenide high‐temperature superconductor.

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Large As sublattice distortion in sphalerite ZnSnAs2 thin films revealed by x-ray fluorescence holography

Cited by 42 publications

References 34 publications

X‐Ray Fluorescence Holography Analysis of Local Structure in CuInSe₂ and CuGaSe₂

X‐Ray Fluorescence Holography Analysis of Local Structure in CuInSe₂ and CuGaSe₂

Local Structure of FeSe_0.4Te_0.6 by Low‐Temperature X‐Ray Fluorescence Holography

Applications of a L₁‐Regularized Linear Regression to X‐Ray Fluorescence Holography Data of Functional Materials

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Large As sublattice distortion in sphalerite ZnSnAs2 thin films revealed by x-ray fluorescence holography

Cited by 42 publications

References 34 publications

X‐Ray Fluorescence Holography Analysis of Local Structure in CuInSe2 and CuGaSe2

X‐Ray Fluorescence Holography Analysis of Local Structure in CuInSe2 and CuGaSe2

Local Structure of FeSe0.4Te0.6 by Low‐Temperature X‐Ray Fluorescence Holography

Applications of a L1‐Regularized Linear Regression to X‐Ray Fluorescence Holography Data of Functional Materials

Contact Info

Product

Resources

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X‐Ray Fluorescence Holography Analysis of Local Structure in CuInSe₂ and CuGaSe₂

X‐Ray Fluorescence Holography Analysis of Local Structure in CuInSe₂ and CuGaSe₂

Local Structure of FeSe_0.4Te_0.6 by Low‐Temperature X‐Ray Fluorescence Holography

Applications of a L₁‐Regularized Linear Regression to X‐Ray Fluorescence Holography Data of Functional Materials