X-ray ptychography with extended depth of field

Tsai, Esther H. R.; Usov, Ivan; Díaz, Ana; Menzel, Andreas; Guizar‐Sicairos, Manuel

doi:10.1364/oe.24.029089

Cited by 120 publications

(83 citation statements)

References 48 publications

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“…When combined with the Rayleigh resolution of Eq. 2, the DOF can be written as

DOF = 2 δ_{z} = \frac{2}{{0.61}^{2}} \frac{δ_{r}^{2}}{λ} ≃ 5.4 δ_{r} \frac{δ_{r}}{λ},

which agrees well with experimental observations for absorption contrast imaging in a scanning transmission x-ray microscope [19] as well as with multiple-plane x-ray ptychography observations [20]. That is, as the transverse resolution approaches the x-ray wavelength, the DOF approaches the transverse resolution.…”

Section: Beyond the Pure Projection Approximationsupporting

confidence: 85%

“…When using a circular lens, the depth of focus (DOF) of an image is given by [19]

DOF = \frac{2}{{0.61}^{2}} \frac{δ_{r}^{2}}{λ} ≃ 5.4 δ_{r} \frac{δ_{r}}{λ},

while

DOF = 5.2 δ_{r}^{2} / λ

has been found to describe the depth of focus of x-ray ptychographic images [20]. For samples with an overall dimension less than the equivalent depth of focus of the imaging approach used, each view as the object is rotated can be treated as representing a pure projection for use in a standard tomographic reconstruction algorithm.…”

Section: Introductionmentioning

confidence: 99%

“…In the reconstruction process, the probe and object functions are updated at each plane, since the ptychographic update steps work to maximize the separability of object and probe. Using this multislice approach, images have been obtained of a few discrete, separated planes by using a single viewing direction [20, 25–28] or a limited range of tilt angles [29]. …”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

3D x-ray imaging of continuous objects beyond the depth of focus limit

Gilles¹,

Nashed²,

Du³

et al. 2018

Optica

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X-ray ptychography is becoming the standard method for sub-30 nm imaging of thick extended samples. Available algorithms and computing power have traditionally restricted sample reconstruction to 2D slices. We build on recent progress in optimization algorithms and high performance computing to solve the ptychographic phase retrieval problem directly in 3D. Our approach addresses samples that do not fit entirely within the depth of focus of the imaging system. Such samples pose additional challenges because of internal diffraction effects within the sample. We demonstrate our approach on a computational sample modeled with 17 million complex variables.

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“…When combined with the Rayleigh resolution of Eq. 2, the DOF can be written as

DOF = 2 δ_{z} = \frac{2}{{0.61}^{2}} \frac{δ_{r}^{2}}{λ} ≃ 5.4 δ_{r} \frac{δ_{r}}{λ},

Section: Beyond the Pure Projection Approximationsupporting

confidence: 85%

“…When using a circular lens, the depth of focus (DOF) of an image is given by [19]

DOF = \frac{2}{{0.61}^{2}} \frac{δ_{r}^{2}}{λ} ≃ 5.4 δ_{r} \frac{δ_{r}}{λ},

while

DOF = 5.2 δ_{r}^{2} / λ

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

3D x-ray imaging of continuous objects beyond the depth of focus limit

Gilles¹,

Nashed²,

Du³

et al. 2018

Optica

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show abstract

“…This assumption gives rise to the limited depth of field, which poses a compromise between the object size and image resolution. For the current sample thickness and the energy used in this experiment, the resolution and image quality become suboptimal at resolutions below 50 nm due to this effect 49 . The multi-slice methods 49–52 , in which the object is represented by multiple axial slices in the reconstruction to account for multiple scattering effects, provide a promising means to image even larger volumes with nanometer resolution, opening up new possibilities for thick biological tissue nanotomography.…”

Section: Discussionmentioning

confidence: 99%

Three-Dimensional Imaging of Biological Tissue by Cryo X-Ray Ptychography

Shahmoradian

Tsai

Díaz

et al. 2017

Sci Rep

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High-throughput three-dimensional cryogenic imaging of thick biological specimens is valuable for identifying biologically- or pathologically-relevant features of interest, especially for subsequent correlative studies. Unfortunately, high-resolution imaging techniques at cryogenic conditions often require sample reduction through sequential physical milling or sectioning for sufficient penetration to generate each image of the 3-D stack. This study represents the first demonstration of using ptychographic hard X-ray tomography at cryogenic temperatures for imaging thick biological tissue in a chemically-fixed, frozen-hydrated state without heavy metal staining and organic solvents. Applied to mammalian brain, this label-free cryogenic imaging method allows visualization of myelinated axons and sub-cellular features such as age-related pigmented cellular inclusions at a spatial resolution of ~100 nanometers and thicknesses approaching 100 microns. Because our approach does not require dehydration, staining or reduction of the sample, we introduce the possibility for subsequent analysis of the same tissue using orthogonal approaches that are expected to yield direct complementary insight to the biological features of interest.

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“…Instead of pursuing the 3D imaging performance of multislice ptychography, here we demonstrate its ability to extend the depth of field via an optical experiment. This has been demonstrated in x-ray regime [6], although in this case the breakdown of the multiplicative approximation is nowhere near as severe as that in the visible light regime, due to the strong penetration power of x-rays. …”

Section: Introductionmentioning

confidence: 92%

Optical ptychography with extended depth of field

Maiden

2017

J. Phys.: Conf. Ser.

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Abstract.Ptychography is an increasingly popular phase imaging technique. However, like any imaging technique it has a depth of field that limits the volume of a thick specimen that can be imaged in focus. Here, we have proposed to extend the depth of field using a multislice calculation model; an optical experiment successfully demonstrates our proposal. IntroductionPtychography is a coherent diffraction imaging technique that can deliver quantitative phase information at diffraction limited resolution [1]. Its conventional implementation requires a coherent illumination of finite extent to be scanned over a specimen at a raster grid of positions and the corresponding diffraction patterns to be recorded by a camera somewhere downstream [2]. The illuminated area between adjacent positions needs to partially overlap, such that redundant information exists in the recorded diffraction patterns. Since only the intensity is detected (the phase information is lost), a phase retrieval algorithm is needed to re-phase the recorded diffraction patterns and reconstruct the complex transmission function of the specimen.However, ptychography has a limited depth of field; it requires the specimen to be thin enough such that the wavefront that exits the specimen (the exit wave) is accurately approximated by the product of the illumination function and the transmission function of the specimen [2,3], as shown in Fig. 1a. Under the Born approximation, the depth of field of ptychography is given by Eq. (1) and explained in Fig. 1b [4]:

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X-ray ptychography with extended depth of field

Cited by 120 publications

References 48 publications

3D x-ray imaging of continuous objects beyond the depth of focus limit

3D x-ray imaging of continuous objects beyond the depth of focus limit

Three-Dimensional Imaging of Biological Tissue by Cryo X-Ray Ptychography

Optical ptychography with extended depth of field

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