In Tandem Control of La-Doping and CuO-Heterojunction on SrTiO3 Perovskite by Double-Nozzle Flame Spray Pyrolysis: Selective H2 vs. CH4 Photocatalytic Production from H2O/CH3OH

Psathas, Pavlos; Zindrou, Areti; Papachristodoulou, C.; Boukos, N.; Deligiannakis, Yiannis

doi:10.3390/nano13030482

Cited by 11 publications

(11 citation statements)

References 74 publications

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“…We underline that these size distributions are a result of at least 100 particles and were obtained from several TEM images. These results are in good agreement with the structural characterization results of FSP-made SrTiO 3 particles from our previous work [ 25 ]. Comparison of d XRD and d TEM reveals a well-known effect in which larger particles dominate the diffraction patterns, while the contribution of smaller particles is less visible.…”

Section: Resultssupporting

confidence: 92%

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Flame Spray Pyrolysis Synthesis of Vo-Rich Nano-SrTiO3-x

Zindrou,

Psathas,

Deligiannakis

2024

Nanomaterials

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Engineering of oxygen vacancies (Vo) in nanomaterials allows diligent control of their physicochemical properties. SrTiO3 possesses the typical ABO3 structure and has attracted considerable attention among the titanates due to its chemical stability and its high conduction band energy. This has resulted in its extensive use in photocatalytic energy-related processes, among others. Herein, we introduce the use of Flame Spray Pyrolysis (FSP); an industrial and scalable process to produce Vo-rich SrTiO3 perovskites. We present two types of Anoxic Flame Spray Pyrolysis (A-FSP) technologies using CH4 gas as a reducing source: Radial A-FSP (RA-FSP); and Axial A-FSP (AA-FSP). These are used for the control engineering of oxygen vacancies in the SrTiO3-x nanolattice. Based on X-ray photoelectron spectroscopy, Raman and thermogravimetry-differential thermal analysis, we discuss the role and the amount of the Vos in the so-produced nano-SrTiO3-x, correlating the properties of the nanolattice and energy-band structure of the SrTiO3-x. The present work further corroborates the versatility of FSP as a synthetic process and the potential future application of this process to engineer photocatalysts with oxygen vacancies in quantities that can be measured in kilograms.

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Section: Resultssupporting

confidence: 92%

“…Previously, Yuan et al presented FSP-made SrTiO 3 with dopings of Co, Fe, Mn, Ni and Cu [ 23 , 24 ]. Our previous work showcased La-doping and CuO-heterojunction on SrTiO 3 enhancement and selective H 2 vs. CH 4 photocatalytic production from H 2 O/CH 3 OH [ 25 ].…”

Section: Introductionmentioning

confidence: 99%

Flame Spray Pyrolysis Synthesis of Vo-Rich Nano-SrTiO3-x

Zindrou,

Psathas,

Deligiannakis

2024

Nanomaterials

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“…In the DN-FSP configuration, TiO 2 and RuO 2 nanoparticles were formed separately using two FSP nozzles, code-named Nozzle-1 and Nozzle-2, respectively (refer to Figure D). After a series of optimizations, ,, an asymmetrical DN-FSP setup was employed (see Figure B,D), where the two nozzles were arranged at specific intersection distances and angles. Specifically, Nozzle-2, dedicated to the synthesis of RuO 2 , was positioned at an angle of β = 30° and a distance of 64 cm from the particle-collection glass-fiber filter.…”

Section: Experimental Sectionmentioning

confidence: 99%

Industrial-Scale Engineering of Nano {RuO₂/TiO₂} for Photocatalytic Water Splitting: The Distinct Role of {(Rutile)TiO₂–(Rutile)RuO₂} Interfacing

Solakidou,

Zindrou,

Smykała

et al. 2024

Ind. Eng. Chem. Res.

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Photocatalytic RuO 2 /TiO 2 nanohybrids have been engineered using flame spray pyrolysis (FSP) technology, enabling the selective formation of either {(rutile)TiO 2 −(rutile)RuO 2 } or {(anatase)TiO 2 −(rutile)RuO 2 } nanointerphase in a single step. The {(rutile)TiO 2 −(rutile)RuO 2 } nanohybrids were selectively produced by using a double-nozzle FSP (DN-FSP) process. The {(anatase)-TiO 2 −(rutile)RuO 2 } nanohybrids were selectively produced using a single-nozzle FSP (SN-FSP) process. Both RuO 2 /TiO 2 nanohybrids exhibited significant photocatalytic H 2 and O 2 production from H 2 O. Notably, the {(rutile)TiO 2 −(rutile)RuO 2 } is shown to be a superior photocatalyst, achieving H 2 evolution rates exceeding 5144 μmol g −1 h −1 H 2 and 2369 μmol g −1 h −1 O 2 under solar light illumination. This performance is 50% higher than that of the {(anatase)TiO 2 − (Rutile)RuO 2 } configuration. In situ EPR spectroscopy reveals that stable Ti 3+ /Ru 5+ centers are formed during the FSP process, in the {(rutile)TiO 2 −(rutile)RuO 2 } interphase. This highlights a unique interfacial electron-transfer event, which is ascribed to a strong oxide (RuO 2 )/support (TiO 2 ) interaction (SOSI), further validated by transmission electron microscopy/scanning transmission electron microscopy. From a technological perspective, FSP fosters a robust {rutile−rutile} interface between the semimetal−RuO 2 and the TiO 2 semiconductor, which is beneficial for the separation of interfacial electron−hole pairs onto TiO 2 and RuO 2 particles. Double-nozzle FSP technology, as demonstrated in this study, offers a promising engineering approach for the industrial production of high-efficiency photocatalytic materials.

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“…The dopant concentration significantly controlled the selective production of H2 or CH4 from H2O/CH3OH. CuO incorporation drastically shifted production to CH4, achieving a rate of 1.5 mmol g −1 h −1 for the La:SrTiO3/CuO catalyst (0.5 wt%) [58]. TiO 2 : Grossmann et al, through the utilization of DN-FSP, produced TiO 2 with deposited Pt particles [67].…”

Section: Double-nozzle Fsp Configurationmentioning

confidence: 99%

Advanced Flame Spray Pyrolysis (FSP) Technologies for Engineering Multifunctional Nanostructures and Nanodevices

Dimitriou,

Psathas,

Solakidou

et al. 2023

Nanomaterials

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Flame spray pyrolysis (FSP) is an industrially scalable technology that enables the engineering of a wide range of metal-based nanomaterials with tailored properties nanoparticles. In the present review, we discuss the recent state-of-the-art advances in FSP technology with regard to nanostructure engineering as well as the FSP reactor setup designs. The challenges of in situ incorporation of nanoparticles into complex functional arrays are reviewed, underscoring FSP’s transformative potential in next-generation nanodevice fabrication. Key areas of focus include the integration of FSP into the technology readiness level (TRL) for nanomaterials production, the FSP process design, and recent advancements in nanodevice development. With a comprehensive overview of engineering methodologies such as the oxygen-deficient process, double-nozzle configuration, and in situ coatings deposition, this review charts the trajectory of FSP from its foundational roots to its contemporary applications in intricate nanostructure and nanodevice synthesis.

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In Tandem Control of La-Doping and CuO-Heterojunction on SrTiO3 Perovskite by Double-Nozzle Flame Spray Pyrolysis: Selective H2 vs. CH4 Photocatalytic Production from H2O/CH3OH

Cited by 11 publications

References 74 publications

Flame Spray Pyrolysis Synthesis of Vo-Rich Nano-SrTiO3-x

Flame Spray Pyrolysis Synthesis of Vo-Rich Nano-SrTiO3-x

Industrial-Scale Engineering of Nano {RuO₂/TiO₂} for Photocatalytic Water Splitting: The Distinct Role of {(Rutile)TiO₂–(Rutile)RuO₂} Interfacing

Advanced Flame Spray Pyrolysis (FSP) Technologies for Engineering Multifunctional Nanostructures and Nanodevices

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In Tandem Control of La-Doping and CuO-Heterojunction on SrTiO3 Perovskite by Double-Nozzle Flame Spray Pyrolysis: Selective H2 vs. CH4 Photocatalytic Production from H2O/CH3OH

Cited by 11 publications

References 74 publications

Flame Spray Pyrolysis Synthesis of Vo-Rich Nano-SrTiO3-x

Flame Spray Pyrolysis Synthesis of Vo-Rich Nano-SrTiO3-x

Industrial-Scale Engineering of Nano {RuO2/TiO2} for Photocatalytic Water Splitting: The Distinct Role of {(Rutile)TiO2–(Rutile)RuO2} Interfacing

Advanced Flame Spray Pyrolysis (FSP) Technologies for Engineering Multifunctional Nanostructures and Nanodevices

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Product

Resources

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Industrial-Scale Engineering of Nano {RuO₂/TiO₂} for Photocatalytic Water Splitting: The Distinct Role of {(Rutile)TiO₂–(Rutile)RuO₂} Interfacing