Glancing Angle Deposition in Gas Sensing: Bridging Morphological Innovations and Sensor Performances

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Detalles Bibliográficos
Publicado en:	Nanomaterials vol. 15, no. 14 (2025), p. 1136-1217
Autor principal:	Singh Shivam
Otros Autores:	Stiwinter, Kenneth Christopher, Singh, Jitendra Pratap, Zhao, Yiping
Publicado:	MDPI AG
Materias:	Nanoparticles Nitrogen dioxide Gas sensors Structural engineering Volatile organic compounds > VOCs Graphene Pattern recognition Islands Data analysis Nanofabrication Pattern analysis Nanostructure Metals Artificial intelligence Nanorods Real time Metal oxides Deposition Organic compounds Adsorption Aspect ratio Batch processing Hydrogen sulfide Heterojunctions Innovations Charge transfer Catalytic activity Detection limits Porosity Gases Piezoelectricity Fabrication Substrates Temperature Sensors Chemical vapor deposition Noble metals Morphology Reproducibility Signal transduction
Acceso en línea:	Citation/Abstract Full Text + Graphics Full Text - PDF
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Descripción
Resumen:	Glancing Angle Deposition (GLAD) has emerged as a versatile and powerful nanofabrication technique for developing next-generation gas sensors by enabling precise control over nanostructure geometry, porosity, and material composition. Through dynamic substrate tilting and rotation, GLAD facilitates the fabrication of highly porous, anisotropic nanostructures, such as aligned, tilted, zigzag, helical, and multilayered nanorods, with tunable surface area and diffusion pathways optimized for gas detection. This review provides a comprehensive synthesis of recent advances in GLAD-based gas sensor design, focusing on how structural engineering and material integration converge to enhance sensor performance. Key materials strategies include the construction of heterojunctions and core–shell architectures, controlled doping, and nanoparticle decoration using noble metals or metal oxides to amplify charge transfer, catalytic activity, and redox responsiveness. GLAD-fabricated nanostructures have been effectively deployed across multiple gas sensing modalities, including resistive, capacitive, piezoelectric, and optical platforms, where their high aspect ratios, tailored porosity, and defect-rich surfaces facilitate enhanced gas adsorption kinetics and efficient signal transduction. These devices exhibit high sensitivity and selectivity toward a range of analytes, including NO2, CO, H2S, and volatile organic compounds (VOCs), with detection limits often reaching the parts-per-billion level. Emerging innovations, such as photo-assisted sensing and integration with artificial intelligence for data analysis and pattern recognition, further extend the capabilities of GLAD-based systems for multifunctional, real-time, and adaptive sensing. Finally, current challenges and future research directions are discussed, emphasizing the promise of GLAD as a scalable platform for next-generation gas sensing technologies.
ISSN:	2079-4991
DOI:	10.3390/nano15141136
Fuente:	Materials Science Database