30
                nm
           resolution x-ray imaging at 8keV using third order diffraction of a zone plate lens objective in a transmission microscope

Yin, Gung‐Chian; Song, Yen‐Fang; Tang, Mau‐Tsu; Chen, Fu‐Rong; Liang, K. S.; Duewer, Frederick; Feser, Michael; Yun, Wenbing; Shieh, Han–Ping D.

doi:10.1063/1.2397483

Cited by 109 publications

(61 citation statements)

References 14 publications

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“…The ideal illumination should be as homogeneous and as intense as possible and its numerical aperture should be matched to that of the objective lens in order to obtain optimum resolution. Condensing x-rays with Fresnel zone plates (FZPs) [4], tapered capillaries [5], mirrors [6] or combinations of these devices [7] is a common solution. These optics focus the beam into a Gaussian-shaped spot, normally smaller than the field of view of the microscope, which therefore requires the condenser to be scanned along the direction transverse to the beam to partially overcome this inhomogeneous illumination.…”

Section: Instrumentationmentioning

confidence: 99%

Hard X-ray Phase-Contrast Tomographic Nanoimaging

Stampanoni¹,

Marone²,

Vila‐Comamala³

et al. 2011

AIP Conference Proceedings

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Abstract. Synchrotron-based full-field tomographic microscopy established itself as a tool for noninvasive investigations. Many beamlines worldwide routinely achieve micrometer spatial resolution while the isotropic 100-nm barrier is reached and trespassed only by few instruments, mainly in the soft x-ray regime. We present an x-ray, full-field microscope with tomographic capabilities operating at 10 keV and with a 3D isotropic resolution of 144 nm recently installed at the TOMCAT beamline of the Swiss Light Source. Custom optical components, including a beam-shaping condenser and phase-shifting dot arrays, were used to obtain an ideal, aperture-matched sample illumination and very sensitive phase-contrast imaging. The instrument has been successfully used for the nondestructive, volumetric investigation of single, unstained cells.

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Section: Instrumentationmentioning

confidence: 99%

Hard X-ray Phase-Contrast Tomographic Nanoimaging

Stampanoni¹,

Marone²,

Vila‐Comamala³

et al. 2011

AIP Conference Proceedings

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“…During the past two decades, the development of advanced x-ray optical devices, such as Fresnel zone plates, coupled with the high brilliance of synchrotron x-ray sources, has vastly increased the resolution of x-ray imaging. Resolution for 2D imaging down to 12-30 nm has been recently reported [1][2][3][4]; meanwhile 3D resolution to 30-60 nm and below is also now widely available [5][6][7]. This nano-CT technique has demonstrated many advantages in studying the 3D structures of complex samples at various length scales and has satisfied applications in a wide range of fields, such as material science [8][9], cellular biology [10][11][12], solid oxide fuel cells [13][14], and environmental science [15][16][17].…”

Section: Introductionmentioning

confidence: 99%

The Best of Both Worlds: 3D X-ray Microscopy with Ultra-high Resolution and a Large Field of View

Li¹,

Gelb²,

Yang³

et al. 2011

AIP Conference Proceedings

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Abstract. 3D visualizations of complex structures within various samples have been achieved with high spatial resolution by X-ray computed nanotomography (nano-CT). While high spatial resolution generally comes at the expense of field of view (FOV). Here we proposed an approach that stitched several 3D volumes together into a single large volume to significantly increase the size of the FOV while preserving resolution. Combining this with nano-CT, 18-m FOV with sub-60-nm resolution has been achieved for non-destructive 3D visualization of clustered yeasts that were too large for a single scan. It shows high promise for imaging other large samples in the future.

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“…¢ÂàÔÑÏ [36]. ªÊ ÄÔÇØ ÓÇÐÕÅÇÐÑÑÒÕËÚÇÔÍËØ àÎÇÏÇÐÕÑÄ, ÑÔÐÑÄÂÐÐÞØ ÐÂ AEË×ÓÂÍÙËË, ©± ¶ ËÏÇáÕ ÐÂËÄÞÔÛÇÇ ÒÓÑÔÕÓÂÐÔÕÄÇÐÐÑÇ ÓÂÊÓÇÛÇÐËÇ, ÐÑ ÒÓË ×ÑÓÏËÓÑÄÂÐËË ËÊÑÃÓÂÉÇÐËâ Ô ËØ ÒÑÏÑÜßá ÄÑÊÐËÍÂÇÕ ÙÇÎÞÌ ÓâAE ÒÓÑÃÎÇÏ, ÍÑÕÑÓÞÇ ÓÇ-ÛÂáÕÔâ ÔÑÊAEÂÐËÇÏ ÃÇÔÚËÔÎÇÐÐÑÅÑ ÏÐÑÉÇÔÕÄÂ ÏÑAEË×Ë-ÍÂÙËÌ ÃÂÊÑÄÑÌ ÏÑAEÇÎË [37].…”

unclassified

X-ray microscopy

Лидер¹

2017

Usp. Fiz. Nauk

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±ÑÎÂÅÂâ sqap % l f m al coh (ÅAEÇ l coh ì ÒÑÒÇÓÇÚÐÂâ ÍÑÅÇ-ÓÇÐÕÐÑÔÕß ÒÖÚÍÂ) Ë ËÔÒÑÎßÊÖâ ×ÑÓÏÖÎÖ (3), ÒÓËÄÇAEÈÏ ÄÞÓÂÉÇÐËÇ (7) AEÎâ ³´²® Í ÔÎÇAEÖáÜÇÏÖ ÄËAEÖ: X-ray microscopy is a technique for obtaining real-space two-or three-dimensional images of an object using elements of the focusing optics. In this paper, various types of microscopes are reviewed and their applicability is examined; methods for obtaining image contrast are discussed, and directions for the further development of X-ray microscopy are outlined.

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30 nm resolution x-ray imaging at 8keV using third order diffraction of a zone plate lens objective in a transmission microscope

Cited by 109 publications

References 14 publications

Hard X-ray Phase-Contrast Tomographic Nanoimaging

Hard X-ray Phase-Contrast Tomographic Nanoimaging

The Best of Both Worlds: 3D X-ray Microscopy with Ultra-high Resolution and a Large Field of View

X-ray microscopy

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