Toward the use of CVD-grown MoS₂ nanosheets as field-emission source

Scholarly Works

• Mahajan, A.; Khan, M.; Umapathy, G. R.; Jha, M.; Ghosh, S. Unraveling the Augmented Field Emission Performance of Molybdenum Disulfide-Praseodymium Sulfide (MoS2@PrS) Heterostructure: A Combined Experimental and First Principles-Based Study. Small (Weinheim an der Bergstrasse, Germany) 2024, 21, e2408831. doi:10.1002/smll.202408831
• Zhao, W.; Zhou, J.; Wang, L.; Jin, W.; Kong, Y.; Chu, Y.; Li, J. Pb6Ba3Si2S8I10: a new thiohalide with a quasi-two-dimensional structure and wide band gap. Dalton transactions (Cambridge, England : 2003) 2024, 53, 17200–17206. doi:10.1039/d4dt02315c
• Wang, H.; Pan, X.; Pan, S.; Li, J. Chemical modulation of AIREIIICIVQVI4 family compounds for band gap and optical anisotropy enhancement. Inorganic Chemistry Frontiers 2024, 11, 6919–6927. doi:10.1039/d4qi01738b
• Mahajan, A.; Jha, M.; Arora, A.; Umapathy, G. R.; Ghosh, S. Synthesis of MoS2@NdS heterostructures featuring augmented field emission performance. Journal of Materials Chemistry A 2024, 12, 25274–25290. doi:10.1039/d4ta03897e
• Kong, Y.; Wang, H.; Zhao, W.; Sun, Q.; Li, J.; Pan, S. β-CsHg2I5, a compound with rare [Hg2I5] dimers and large optical anisotropy. Dalton transactions (Cambridge, England : 2003) 2024, 53, 12090–12097. doi:10.1039/d4dt01536c
• Tripathi, M.; Deokar, G.; Casanova-Chafer, J.; Jin, J.; Sierra-Castillo, A.; Ogilvie, S. P.; Lee, F.; Iyengar, S. A.; Biswas, A.; Haye, E.; Genovese, A.; Llobet, E.; Colomer, J.-F.; Jurewicz, I.; Gadhamshetty, V.; Ajayan, P. M.; Schwingenschlögl, U.; Costa, P. M. F. J.; Dalton, A. B. Vertical heterostructure of graphite-MoS2 for gas sensing. Nanoscale horizons 2024, 9, 1330–1340. doi:10.1039/d4nh00049h
• Al Qaydi, M.; Rajput, N. S.; Lejeune, M.; Bouchalkha, A.; El Marssi, M.; Cordette, S.; Kasmi, C.; Jouiad, M. Intermixing of MoS2 and WS2 photocatalysts toward methylene blue photodegradation. Beilstein journal of nanotechnology 2024, 15, 817–829. doi:10.3762/bjnano.15.68
• Mouloua, D.; Kaja, K.; Lejeune, M.; Zeinert, A.; El Marssi, M.; El Khakani, M. A.; Jouiad, M. Scalable and Contactless Optical Dye Sensors Based on Differential Reflectivity of Excitonic Peaks by MoS2 Nanostructures. ACS Applied Nano Materials 2024, 7, 9366–9374. doi:10.1021/acsanm.4c00853
• Mouloua, D.; LeBlanc‐Lavoie, J.; Pichon, L.; Rajput, N. S.; El Marssi, M.; Jouiad, M.; El Khakani, M. A. Tuning the Optoelectronic Properties of Pulsed Laser Deposited "3D"‐MoS2 Films via the Degree of Vertical Alignment of Their Constituting Layers. Advanced Optical Materials 2024, 12. doi:10.1002/adom.202302966
• Zhou, J.; Wang, L.; Wang, H.; Luo, L.; Li, J.; Yu, F. Ba3(BS3)(PS4): the first alkaline-earth metal thioborate-thiophosphate with strong optical anisotropy originating from planar [BS3] units. Dalton transactions (Cambridge, England : 2003) 2023, 52, 16113–16117. doi:10.1039/d3dt02807k
• kumar, S.; Pratap, S.; Joshi, N.; Trivedi, R.; Rout, C. S.; Chakraborty, B. Recent development of two-dimensional tantalum dichalcogenides and their applications. Micro and Nanostructures 2023, 181, 207627. doi:10.1016/j.micrna.2023.207627
• Chen, Y.; Chen, J.; Li, Z. Cold Cathodes with Two-Dimensional van der Waals Materials. Nanomaterials (Basel, Switzerland) 2023, 13, 2437. doi:10.3390/nano13172437
• Sethulekshmi, A.; Saritha, A.; Joseph, K.; Aprem, A. S.; Sisupal, S. B.; Sidharth, G.; Nair, V. S. Tannic acid as a green exfoliating agent: A sustainable pathway towards the development of natural rubber- molybdenum disulfide nanocomposites. Industrial Crops and Products 2023, 192, 115978. doi:10.1016/j.indcrop.2022.115978
• Mouloua, D.; Rajput, N. S.; Saitzek, S.; Kaja, K.; Hoummada, K.; El Marssi, M.; El Khakani, M. A.; Jouiad, M. Broadband photodetection using one-step CVD-fabricated MoS2/MoO2 microflower/microfiber heterostructures. Scientific reports 2022, 12, 22096. doi:10.1038/s41598-022-26185-z
• Mouloua, D.; Rajput, N.; Blach, J.-F.; Lejeune, M.; El Marssi, M.; El Khakani, M.; Jouiad, M. Fabrication control of MoS2/MoO2 nanocomposite via chemical vapor deposition for optoelectronic applications. Materials Science and Engineering: B 2022, 286, 116035. doi:10.1016/j.mseb.2022.116035
• Guan, Z.; Li, J.; Wu, H.; Chen, X.; Ou-Yang, W. Stacked conductive metal–organic framework nanorods for high-performance vacuum electronic devices. Ceramics International 2022, 48, 34092–34097. doi:10.1016/j.ceramint.2022.08.238
• Ma, Y.; Liu, Y.; Tan, X.; Shen, T.; Gu, F. Tailoring photoluminescence and optoelectrical properties of MoS2 monolayers on Au interdigital electrodes. Japanese Journal of Applied Physics 2022, 61, 100906. doi:10.35848/1347-4065/ac93d7
• Rajput, N. S.; Kotbi, A.; Kaja, K.; Jouiad, M. Long-term aging of CVD grown 2D-MoS2 nanosheets in ambient environment. npj Materials Degradation 2022, 6. doi:10.1038/s41529-022-00288-4
• Bhopale, S. R.; More, M. A. Systematic Field Electron Emission Investigations of Vapor‐Phase‐Grown Sb2Te3Nanosheets. physica status solidi (a) 2022, 219. doi:10.1002/pssa.202200126
• Sethulekshmi, A. S.; Saritha, A.; Joseph, K.; Aprem, A. S.; Sisupal, S. B. MoS2 based nanomaterials: Advanced antibacterial agents for future. Journal of controlled release : official journal of the Controlled Release Society 2022, 348, 158–185. doi:10.1016/j.jconrel.2022.05.047

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