Research Progress on Lanthanum Zirconate Porous Materials for Thermal Insulation

doi:10.15541/jim20250364

Abstract

Abstract:

Lanthanum zirconate porous material is a kind of high porosity materials with nanoparticles or microparticles as the basic building unit. These materials exhibit exceptionally low thermal conductivity and maintain remarkable phase stability up to their melting point, making them particularly promising for thermal insulation applications in the aerospace industry. However, sintering problems of lanthanum zirconate porous materials cause collapse and shrinkage of pore structure, resulting in relatively poor thermal resistance and thermal insulation. Researchers have employed precise control over pore sizes and particle dimensions to optimize the mesostructure, leading to a significant reduction in thermal conductivity. Specifically, template-based methods enable precise control over pore sizes at the micro-nano scale, while Sol-Gel techniques combined with varied drying processes facilitate regulation of particle dimensions at the nanoscale. Concurrently, introduction of single- or multi-element doping has proven effective in inducing controlled lattice distortion, which subsequently weakens thermodynamic diffusion processes and suppresses high-temperature grain growth. This dual strategy of morphological control and compositional engineering has substantially improved both thermal insulation capability and temperature resistance of lanthanum zirconate porous materials. This review begins by introducing crystal structure of lanthanum zirconate, highlighting its advantages in phase stability and doping capability. It then systematically surveys recent developments in fabrication technologies and modification strategies for lanthanum zirconate-based porous thermal insulation materials, with particular emphasis on advances in mesostructural optimization and elemental doping methodologies. A detailed analysis is provided on the distinct mechanisms through which these approaches suppress thermal conduction and enhance high-temperature stability. Finally, this review concludes by outlining promising avenues for future research.

Key words: porous lanthanum zirconate, thermal insulation, structural controlling, element doping, review

CLC Number:

TB332

CHEN Kun, JIANG Yonggang, FENG Junzong, LI Liangjun, HU Yijie, FENG Jian. Research Progress on Lanthanum Zirconate Porous Materials for Thermal Insulation[J]. Journal of Inorganic Materials, 2026, 41(4): 421-431.

Figures/Tables 11

Fig. 1 Schematic diagrams of (a) fluorite and (b) pyrochlore structures[20]

Fig. 2 Phase diagram of the La2O3-ZrO2 system[27]

Fig. 3 Thermal conductivity of LZO modified by binary rare earths as a function of temperature[31]

Fig. 4 Thermal conductivity of porous LZO ceramics at 200-1200 ℃[40]

Fig. 5 Hollow-grained La2Zr2O7 ceramics[41] (a-c) Microstructures of hollow-grained La2Zr2O7 ceramics and (d) corresponding selected area electron diffraction pattern of the bulk; (e) Thermal performance of hollow-grained La2Zr2O7 ceramics; (f) Thermal conductivity of La2Zr2O7 ceramics at various temperatures; (g) Mercury intrusion results with inset showing stacked column chart; (h) Illustration of heat transfer paths

Fig. 6 Microstructures of LZO porous ceramics with different coating contents[45] (a) 13.7%; (b) 10.5%; (c) 6.4%; (d) 4.6%; (e) Micro-computed tomography of LZO porous ceramics (sample with coating content of 10.5%, in volume)

Fig. 7 Pictures and microstructures of the wet gel and aerogels synthesized with different ethanol contents[51] (a-c) E20; (d-f) E40; (g-i) E60

Table 1 Basic properties of lanthanum zirconate porous materials for thermal insulation[47,51 -57]

Precursor	Drying process*	Specific surface area/(m²·g^-1)	Average pore size/nm	Nanoparticle size/nm	Thermal conductivity/ (W·m^-1·K^-1)	Density/ (g·cm^-3)	Ref.
Zr(NO₃)₄·5H₂O La(NO₃)₃·6H₂O	EtOH	413.2	12.3	14.5	-	-	[51]
Zr(NO₃)₄·5H₂O La(NO₃)₃·6H₂O	Ambient pressure drying	302.9	22.2	90.9	-	-	[52]
Zr(CH₃COO)₄La(NO₃)₃·6H₂O	EtOH	325.17	40-50	25-35	0.071 (RT)	1.78	[54]
ZrOCl₂·8H₂O La(NO₃)₃·6H₂O	Ambient pressure drying	-	-	40-100	-	-	[55]
Zr(NO₃)₄·5H₂O La(NO₃)₃·6H₂O	Freeze drying	594.85	36-45	20-28	0.033 (RT) 0.051 (800 ℃)	-	[53]
Zr(OPr)₄La(NO₃)₃·6H₂O	CO₂	100	40	70	-	-	[56]
Zr(NO₃)₄·5H₂O La(NO₃)₃·6H₂O	Ambient pressure drying	89	3.7	70	-	-	[47]
Zr(NO₃)₄·5H₂O La(NO₃)₃·6H₂O	EtOH	470.8	22.3	12.74	-	-	[57]

Fig. 8 Specific surface area and pore structure of silicon-doped LZS aerogels[57] (a) N2 adsorption-desorption isotherms; (b) Pore size distribution curves; (c) Specific surface area and pore volume of LZS aerogels at 1000 ℃ heat treatment; (d) Specific surface area and porosity of LZS0 and LZS10 aerogels at different heat temperatures

Fig. 9 Compositions, structures and properties of (LaCeSmEuNd)2Zr2O7 aerogels[61] (a-f) SEM images of (LaCeNdSmEu)2Zr2O7 ceramics calcined at (a, d) 750, (b, e) 950 and (c, f) 1150 ℃; (g) EDS-mappings of the sample calcined at 950 ℃; (h) Diameter shrinkage of cylindrical samples and photographs of LZO and RZO as pressed and annealed at 1200 and 1400 ℃ for 2 h; (i) Thermal conductivities of RZO and LZO at 25 ℃ and compressive strength of RZO

Fig. 10 Thermal conductivities and insulating properties of FARZ[63] (a) Thermal conductivities of FARZ as a function of density; (b) Thermal conductivities at room temperature in air and crystalline temperature for high entropy materials; (c) Optical image and (d) time-dependent temperature evolution on the back side of FARZ mullite fiber exposed to a butane blowtorch flame

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