Enhanced Performance of La2NiO4+δ Oxygen-Transporting Membranes Using Crystal Facet Engineering via Microemulsion-Based Synthesis

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Giamper Escobar Cano
  • Merle Wellmann
  • Frank Steinbach
  • Moritz Thiem
  • Wenjie Xie
  • Anke Weidenkaff
  • Armin Feldhoff

Externe Organisationen

  • Technische Universität Darmstadt
  • Fraunhofer-Einrichtung für Wertstoffkreisläufe und Ressourcenstrategie (IWKS)
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Details

OriginalspracheEnglisch
Seiten (von - bis)9557-9574
Seitenumfang18
FachzeitschriftChemistry of materials
Jahrgang36
Ausgabenummer19
Frühes Online-Datum24 Sept. 2024
PublikationsstatusVeröffentlicht - 8 Okt. 2024

Abstract

La2NiO4+δ nanorods, synthesized via reverse microemulsion─a crystal facet engineering method─served as building blocks for developing oxygen transport membranes. Comparisons were drawn with ceramic membranes derived from commercial La2NiO4+δ nanoparticles. The membrane manufacturing process involved either conventional sintering or the field-assisted sintering technique/spark plasma sintering. The microstructure analysis of the initial powders and the resulting ceramics was thoroughly assessed by X-ray diffraction, scanning and transmission electron microscopy as well as energy-dispersive X-ray spectroscopy. As a consequence of the reaction conditions, the nanorods possess an orthorhombic crystal structure, with LaOBr present as a minor phase. Furthermore, the surface structure of the La2NiO4+δ nanorods was discerned via selected area electron diffraction, revealing a composition of (001)o-type and (1Formula Presented0)o-type facets on the sides and (110)o-type facets at the end, with additional facets observed between these surfaces. Among the sintering techniques, spark plasma sintering demonstrated superior performance, when applied to La2NiO4+δ nanorods, as it effectively preserved their rod-like nanostructure during the sintering process. The resulting nanorod-derived La2NiO4+δ ceramics exhibited excellent oxygen permeation, largely due to the large proportion of orthorhombic (1Formula Presented0)o-type surfaces in the rod-shaped grains, which correspond to tetragonal (010)t and (0Formula Presented0)t surfaces. The (1Formula Presented0)o-type facets facilitated the oxygen surface exchange, leading to improved oxygen permeation fluxes between 1023 and 1123 K compared to membranes derived from nanoparticles.

ASJC Scopus Sachgebiete

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Enhanced Performance of La2NiO4+δ Oxygen-Transporting Membranes Using Crystal Facet Engineering via Microemulsion-Based Synthesis. / Escobar Cano, Giamper; Wellmann, Merle; Steinbach, Frank et al.
in: Chemistry of materials, Jahrgang 36, Nr. 19, 08.10.2024, S. 9557-9574.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Escobar Cano G, Wellmann M, Steinbach F, Thiem M, Xie W, Weidenkaff A et al. Enhanced Performance of La2NiO4+δ Oxygen-Transporting Membranes Using Crystal Facet Engineering via Microemulsion-Based Synthesis. Chemistry of materials. 2024 Okt 8;36(19):9557-9574. Epub 2024 Sep 24. doi: 10.1021/acs.chemmater.4c01570
Escobar Cano, Giamper ; Wellmann, Merle ; Steinbach, Frank et al. / Enhanced Performance of La2NiO4+δ Oxygen-Transporting Membranes Using Crystal Facet Engineering via Microemulsion-Based Synthesis. in: Chemistry of materials. 2024 ; Jahrgang 36, Nr. 19. S. 9557-9574.
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title = "Enhanced Performance of La2NiO4+δ Oxygen-Transporting Membranes Using Crystal Facet Engineering via Microemulsion-Based Synthesis",
abstract = "La2NiO4+δ nanorods, synthesized via reverse microemulsion─a crystal facet engineering method─served as building blocks for developing oxygen transport membranes. Comparisons were drawn with ceramic membranes derived from commercial La2NiO4+δ nanoparticles. The membrane manufacturing process involved either conventional sintering or the field-assisted sintering technique/spark plasma sintering. The microstructure analysis of the initial powders and the resulting ceramics was thoroughly assessed by X-ray diffraction, scanning and transmission electron microscopy as well as energy-dispersive X-ray spectroscopy. As a consequence of the reaction conditions, the nanorods possess an orthorhombic crystal structure, with LaOBr present as a minor phase. Furthermore, the surface structure of the La2NiO4+δ nanorods was discerned via selected area electron diffraction, revealing a composition of (001)o-type and (1Formula Presented0)o-type facets on the sides and (110)o-type facets at the end, with additional facets observed between these surfaces. Among the sintering techniques, spark plasma sintering demonstrated superior performance, when applied to La2NiO4+δ nanorods, as it effectively preserved their rod-like nanostructure during the sintering process. The resulting nanorod-derived La2NiO4+δ ceramics exhibited excellent oxygen permeation, largely due to the large proportion of orthorhombic (1Formula Presented0)o-type surfaces in the rod-shaped grains, which correspond to tetragonal (010)t and (0Formula Presented0)t surfaces. The (1Formula Presented0)o-type facets facilitated the oxygen surface exchange, leading to improved oxygen permeation fluxes between 1023 and 1123 K compared to membranes derived from nanoparticles.",
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TY - JOUR

T1 - Enhanced Performance of La2NiO4+δ Oxygen-Transporting Membranes Using Crystal Facet Engineering via Microemulsion-Based Synthesis

AU - Escobar Cano, Giamper

AU - Wellmann, Merle

AU - Steinbach, Frank

AU - Thiem, Moritz

AU - Xie, Wenjie

AU - Weidenkaff, Anke

AU - Feldhoff, Armin

N1 - Publisher Copyright: © 2024 The Authors. Published by American Chemical Society.

PY - 2024/10/8

Y1 - 2024/10/8

N2 - La2NiO4+δ nanorods, synthesized via reverse microemulsion─a crystal facet engineering method─served as building blocks for developing oxygen transport membranes. Comparisons were drawn with ceramic membranes derived from commercial La2NiO4+δ nanoparticles. The membrane manufacturing process involved either conventional sintering or the field-assisted sintering technique/spark plasma sintering. The microstructure analysis of the initial powders and the resulting ceramics was thoroughly assessed by X-ray diffraction, scanning and transmission electron microscopy as well as energy-dispersive X-ray spectroscopy. As a consequence of the reaction conditions, the nanorods possess an orthorhombic crystal structure, with LaOBr present as a minor phase. Furthermore, the surface structure of the La2NiO4+δ nanorods was discerned via selected area electron diffraction, revealing a composition of (001)o-type and (1Formula Presented0)o-type facets on the sides and (110)o-type facets at the end, with additional facets observed between these surfaces. Among the sintering techniques, spark plasma sintering demonstrated superior performance, when applied to La2NiO4+δ nanorods, as it effectively preserved their rod-like nanostructure during the sintering process. The resulting nanorod-derived La2NiO4+δ ceramics exhibited excellent oxygen permeation, largely due to the large proportion of orthorhombic (1Formula Presented0)o-type surfaces in the rod-shaped grains, which correspond to tetragonal (010)t and (0Formula Presented0)t surfaces. The (1Formula Presented0)o-type facets facilitated the oxygen surface exchange, leading to improved oxygen permeation fluxes between 1023 and 1123 K compared to membranes derived from nanoparticles.

AB - La2NiO4+δ nanorods, synthesized via reverse microemulsion─a crystal facet engineering method─served as building blocks for developing oxygen transport membranes. Comparisons were drawn with ceramic membranes derived from commercial La2NiO4+δ nanoparticles. The membrane manufacturing process involved either conventional sintering or the field-assisted sintering technique/spark plasma sintering. The microstructure analysis of the initial powders and the resulting ceramics was thoroughly assessed by X-ray diffraction, scanning and transmission electron microscopy as well as energy-dispersive X-ray spectroscopy. As a consequence of the reaction conditions, the nanorods possess an orthorhombic crystal structure, with LaOBr present as a minor phase. Furthermore, the surface structure of the La2NiO4+δ nanorods was discerned via selected area electron diffraction, revealing a composition of (001)o-type and (1Formula Presented0)o-type facets on the sides and (110)o-type facets at the end, with additional facets observed between these surfaces. Among the sintering techniques, spark plasma sintering demonstrated superior performance, when applied to La2NiO4+δ nanorods, as it effectively preserved their rod-like nanostructure during the sintering process. The resulting nanorod-derived La2NiO4+δ ceramics exhibited excellent oxygen permeation, largely due to the large proportion of orthorhombic (1Formula Presented0)o-type surfaces in the rod-shaped grains, which correspond to tetragonal (010)t and (0Formula Presented0)t surfaces. The (1Formula Presented0)o-type facets facilitated the oxygen surface exchange, leading to improved oxygen permeation fluxes between 1023 and 1123 K compared to membranes derived from nanoparticles.

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U2 - 10.1021/acs.chemmater.4c01570

DO - 10.1021/acs.chemmater.4c01570

M3 - Article

AN - SCOPUS:85205916049

VL - 36

SP - 9557

EP - 9574

JO - Chemistry of materials

JF - Chemistry of materials

SN - 0897-4756

IS - 19

ER -

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