Structural Characterization of Porous Materials Using SAS

Melnichenko, Yuri B.

doi:10.1007/978-3-319-01104-2_7

Cited by 3 publications

(11 citation statements)

References 80 publications

(98 reference statements)

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“…Figure b shows Porod plots and their slopes for both slabs shown in Figure a, obtained after subtracting correlation contributions from disordered worm-like mesopores (see the Supporting Information for details of the analysis). In the Porod region, the scattering intensity I relates to the scattering vector modulus Q according to the power law Here, a power law exponent D < 3 indicates a mass fractal structure with a mass fractal dimension D m = D while 3 < D < 4 indicates a surface fractal structure with a surface fractal dimension D s = 6 – D , and D > 4 indicates a nonfractal structure . The mass fractal dimension D m quantifies how the mass of a fractal structure increases with its increasing size where m is the mass contained in a sphere of mesoporous material of radius r .…”

Section: Resultsmentioning

confidence: 90%

“…SAXS patterns of both slabs consist of (a) Guinier region for Q < 0.4 nm –1 , (b) weak correlation peaks in the range of Q = 0.4–1.0 nm –1 , and (c) a Porod region for Q > 1.0 nm –1 . The presence of Guinier and Porod regions indicates a fractal structure made of aggregated nanoparticles . The weak correlation peaks indicate limited pore-to-pore correlation due to the narrow pore size distribution and the uniform pore wall thickness .…”

Section: Resultsmentioning

confidence: 99%

“…(a) Representative small-angle X-ray scattering patterns of nanoparticle-based mesoporous silica monolithic slabs synthesized on PFC liquid (SiO 2 -PFC-rt) and on PTFE (SiO 2 -PTFE-rt) and (b) corresponding Porod plots obtained after subtracting contributions from disordered worm-like mesopores. The black dashed line with a slope of −4 corresponds to the behavior of nonfractal materials obeying the Porod’s law . Intensity scales in both panels are in arbitrary units.…”

Section: Resultsmentioning

confidence: 99%

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Thick Transparent Nanoparticle-Based Mesoporous Silica Monolithic Slabs for Thermally Insulating Window Materials

Marszewski

King

Yan

et al. 2019

ACS Appl. Nano Mater.

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This paper presents a novel template-free water-based sol–gel method to synthesize thick transparent and thermally insulating mesoporous silica monolithic slabs by gelation and drying of a colloidal suspension of silica nanoparticles under ambient conditions. For the first time, mesoporous silica slabs were synthesized on perfluorocarbon liquid substrates to reduce adhesion and enable the gels to shrink freely during aging and drying without incurring significant stress that could cause fracture. The free-standing nanoparticle-based mesoporous silica slabs were disks or squares, with thickness between 1 and 6 mm and porosity around 50%. The slabs had high transmittance and low haze in the visible spectrum due to small nanoparticles (6–12 nm) and pore size (<10 nm), narrow pore size distribution, and optically smooth surfaces (roughness <15 nm). The slabs’ effective thermal conductivity of 104–160 mW m–1 K–1 at room temperature was smaller than that of other mesoporous silicas with similar or even larger porosity reported in the literature. This was attributed to the slabs fractal structure and high mass fractal dimension. The mechanical properties were similar to those of common polymers. The simple synthesis is readily scalable and offers promising materials for window solutions and solar–thermal energy conversion, for example.

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Section: Resultsmentioning

confidence: 90%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Thick Transparent Nanoparticle-Based Mesoporous Silica Monolithic Slabs for Thermally Insulating Window Materials

Marszewski

King

Yan

et al. 2019

ACS Appl. Nano Mater.

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“…As expected, the source flux needed for a clear pore imaging is proportional to the inverse square of the pore size. The flux can be decreased by an appropriate choice of the probing photon energy to reduce the sample thickness down to l  2/ (see (6)). On the other hand, the smallest value of the thickness in ( 7) is limited by the mentioned condition >> and restrictions of a sample manufacturing.…”

Section: The Absorption Contrastmentioning

confidence: 99%

“…On the contrary, a production of laser ceramics needs a careful removal of the micropores 2 . A study of the pores is known to be both fundamental and practical .X-ray porosimetry as a part of general porosimetry [3][4][5] is a fast developing technique based on X-ray small angle scattering 6 and X-ray imaging 7 . At present it profits from current advances in X-ray source development (new generation of synchrotron radiation and laboratory high brightness X-ray sources) as well as of the state-of-the-art X-ray imaging methods, such as phase contrast tomography 8 and ptychography 9,10 .…”

Section: Introductionmentioning

confidence: 99%

Coherent pore-scale imaging: phase contrast and ptychography

Artyukov

Popov

Виноградов

2021

International Conference on X-Ray Lasers 2020

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The paper deals with an analytical study of the problem of pore detection and certification in bulk materials by means of X-ray radiography. The optimum thickness of a sample under X-ray absorption investigation of the pores is found, that can be used for an improvement of the signal-to-noise ratio by the proper X-ray photon energy. In the case of low absorption an X-ray coherent beam can be used for production of phase contrast in the radiographic experiments. We present a simple model to calculate the complex value of the wave field formed by the sample. The model includes two dimensionless parameters: the Fresnel number F= a 2 (λz), where a is the pore radius, λ is the wavelength, z is the sampleto-detector distance and the phase number Φ = akδ, where k = 2π λ and δ is the decrement of the real part of material's relative permittivity. The detailed analysis of the field structure is given with an estimation of the optimal position of the detector. The numerical simulation results are presented as well, which were obtained for the Gaussian type of the pore shape function. The stationary phase method of higher orders has been proven to simplify the Fresnel integral. The developed qualitative visualization of the pores with the help of phase contrast X-ray imaging complements other modern methods of monitoring porous-sensitive materials.

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