Fractal-Percolation Structure Architectonics in Sol-Gel Synthesis

Kononova, I. E.; Kononov, Pavel; Мошников, В. А.; Ignat'ev, S.

doi:10.3390/ijms221910521

Cited by 10 publications

(7 citation statements)

References 29 publications

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“…The analysis of gas sensitivity measurements based on PPD and X-ray phase analysis data allowed us to find the optimal temperature for annealing nanocomposites of a three-component system, SiO 2 –SnO 2 –In 2 O 3 (700 °C). Based on complex studies of AFM, the BET technique and on previous research [ 47 , 48 ], a hierarchical model of the formation of two-component and three-component porous nanocomposites was proposed, presented in Figure 20 and Figure 21 (in the inset, the semiconductor and dielectric grains of nanocomposites are indicated in pink and blue), accordingly. According to the AFM data, it was found that two-component porous nanocomposites, SiO 2 –SnO 2 , were macro–meso–microporous (macropore sizes of 170–180 nm and mesopore sizes of 40–50 nm) and three-component porous nanocomposites, SiO 2 –SnO 2 –In 2 O 3 , were meso–microporous (mesopore sizes of 11–15 nm).…”

Section: Discussionmentioning

confidence: 99%

“…In refs. [ 47 , 48 ], it is shown that the analytical capabilities of atomic force microscopy do not allow for the diagnosis of elements with sizes smaller than the locality of the method; therefore, the micropore system (less than 2 nm in size) cannot be detected. At the same time, the contribution of such pores to the total surface area can be determined by using the BET technique.…”

Section: Introductionmentioning

confidence: 99%

“…It was found that the surface area of the porous nanocomposites calculated by processing atomic force images differed by 2–3 orders of magnitude from the surface area calculated according to the BET data. This indicated the existence of a micropore system of less than 10 nm, which was not diagnosed using AFM [ 47 , 48 ].…”

Section: Introductionmentioning

confidence: 99%

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SnO2-Based Porous Nanomaterials: Sol-Gel Formation and Gas-Sensing Application

Kononova

Мошников

Kononov

2023

Gels

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Porous nanocomposites using two (tin dioxide–silica dioxide) and three (tin dioxide–indium oxide-silica dioxide)-component systems for gas sensors were created with the sol–gel method. To understand some of the physical–chemical processes that occurred during the adsorption of gas molecules on the surface of the produced nanostructures, two models—the Langmuir model and the Brunauer–Emmett–Teller theory—were used to carry out calculations. The results of the phase analysis concerning the interaction between the components during the formation of the nanostructures were obtained through the use of X-ray diffraction, thermogravimetric analysis, the Brunauer–Emmett–Teller technique (to determine the surface areas), the method of partial pressure diagrams in a wide range of temperatures and pressures and the results of the measurement of the nanocomposites’ sensitivity. The analysis allowed us to find the optimal temperature for annealing nanocomposites. The introduction of a semiconductor additive into a two-component system based on tin and silica dioxides significantly increased the sensitivity of the nanostructured layers to reductional reagent gases.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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SnO2-Based Porous Nanomaterials: Sol-Gel Formation and Gas-Sensing Application

Kononova

Мошников

Kononov

2023

Gels

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“…Design of new material structure is a promising way to solve this problem. The most interesting approach is the development of materials with a fractal structure [17]. Fractal TiO 2 gas sensor has excellent performance in acetone detection, which attributed to the high film porosity and fractal like network structures [18].…”

Section: Introductionmentioning

confidence: 99%

Impedance Spectroscopy of Hierarchical Porous Nanomaterials Based on por-Si, por-Si Incorporated by Ni and Metal Oxides for Gas Sensors

Bobkov

Лучинин

Мошников

et al. 2022

Sensors

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Approaches are being developed to create composite materials with a fractal-percolation structure based on intercalated porous matrices to increase the sensitivity of adsorption gas sensors. Porous silicon, nickel-containing porous silicon, and zinc oxide have been synthesized as materials for such structures. Using the impedance spectroscopy method, it has been shown that the obtained materials demonstrate high sensitivity to organic solvent vapors and can be used in gas sensors. A model is proposed that explains the high sensitivity and inductive nature of the impedance at low frequencies, considering the structural features and fractal-percolation properties of the obtained oxide materials.

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“…A distinction is made among zeolites [ 32 , 33 ] based on micropore size, and the groups range from zeolites with small micropores (0.3–0.45 nm, A), through medium (0.55 nm, pentasils) and large (0.75 nm, faujasites, β—0.64 × 0.76 nm) to extra large (>0.8 nm, mordenites).…”

Section: Introductionmentioning

confidence: 99%

Step-By-Step Modeling and Demetallation Experimental Study on the Porous Structure in Zeolites

et al. 2022

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The organization of microporous space in zeolites is discussed. A new step-by-step model is proposed that explains the principles of organizing the hierarchy of microporous space at the stage of assembling zeolites from elements of minimal size: a primary building unit, secondary building units, tertiary building units or building polyhedra, a sodalite cage, and a supercage. To illustrate the stepwise hierarchical porous structure of nanomaterials, the following zeolites with small and large micropores have been selected as the model objects: sodalite (SOD, the maximum diameter of a sphere that can enter the pores is 0.3 nm) and zeolites of type A (LTA, the maximum diameter of a sphere that can enter the pores is 0.41 nm), type X, Y (FAU, the maximum diameter of a sphere that can enter the pores is 0.75 nm), and type BETA (the maximum diameter of a sphere that can enter the pores is 0.67 nm). Two-dimensional and three-dimensional modeling in 3Ds Max software was used. We believe that such an approach will be useful for developing ways to create complex zeolite compositions for specific applications, such as catalysis, where the geometry of the pores determines the size of the molecules entering the voids and computer modeling can play an important predictive role. This work takes a look at specific aspects of using the heat desorption method to study mesoporous materials with a BETA zeolite as an example and presents the results of experimental research into the characteristics of the porous structure of hierarchically structured zeolite materials (specific surface area 180–380 m2/g, external surface area 120–200 m2/g, micropore volume 0.001–0.1 mL/g).

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Fractal-Percolation Structure Architectonics in Sol-Gel Synthesis

Cited by 10 publications

References 29 publications

SnO2-Based Porous Nanomaterials: Sol-Gel Formation and Gas-Sensing Application

SnO2-Based Porous Nanomaterials: Sol-Gel Formation and Gas-Sensing Application

Impedance Spectroscopy of Hierarchical Porous Nanomaterials Based on por-Si, por-Si Incorporated by Ni and Metal Oxides for Gas Sensors

Step-By-Step Modeling and Demetallation Experimental Study on the Porous Structure in Zeolites

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