Literatura académica sobre el tema "Mobile nanoparticles"
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Artículos de revistas sobre el tema "Mobile nanoparticles"
Gong, Shuting, Tianyi Wang, Jiaping Lin y Liquan Wang. "Patterning of Polymer-Functionalized Nanoparticles with Varied Surface Mobilities of Polymers". Materials 16, n.º 3 (1 de febrero de 2023): 1254. http://dx.doi.org/10.3390/ma16031254.
Texto completoKim, Haneul, Muhammad Numan y Changbum Jo. "Catalytic Dehydration of Ethanol over WOx Nanoparticles Supported on MFI (Mobile Five) Zeolite Nanosheets". Catalysts 9, n.º 8 (6 de agosto de 2019): 670. http://dx.doi.org/10.3390/catal9080670.
Texto completoLisovsky, A. F. "Thermodynamics of the consolidation of nanoparticles and a macrowparticle". Science of Sintering 42, n.º 1 (2010): 15–24. http://dx.doi.org/10.2298/sos1001015l.
Texto completoVerberg, Rolf, Alexander Alexeev y Anna C. Balazs. "Modeling the release of nanoparticles from mobile microcapsules". Journal of Chemical Physics 125, n.º 22 (14 de diciembre de 2006): 224712. http://dx.doi.org/10.1063/1.2404955.
Texto completoJosé-Yacamán, M., C. Gutierrez-Wing, M. Miki, D. Q. Yang, K. N. Piyakis y E. Sacher. "Surface Diffusion and Coalescence of Mobile Metal Nanoparticles". Journal of Physical Chemistry B 109, n.º 19 (mayo de 2005): 9703–11. http://dx.doi.org/10.1021/jp0509459.
Texto completoQi, Zhichong, Lunliang Zhang y Wei Chen. "Transport of graphene oxide nanoparticles in saturated sandy soil". Environ. Sci.: Processes Impacts 16, n.º 10 (2014): 2268–77. http://dx.doi.org/10.1039/c4em00063c.
Texto completoPeng, Xinsheng, Baohong Li, Min Hu, Yahao Ling, Yuan Tian, Yanxing Zhou y Yanfang Zhou. "Quantitative Analysis of Matrine in Liquid Crystalline Nanoparticles by HPLC". Journal of Analytical Methods in Chemistry 2014 (2014): 1–4. http://dx.doi.org/10.1155/2014/368682.
Texto completoNivedhita G, Rajeshkumar S, Anitha Roy, Nagalingam M y Lakshmi T. "Maranta arundinacea root assisted zinc oxide nanoparticles and its characterisation using TEM and UV-vis spectroscopy". International Journal of Research in Pharmaceutical Sciences 11, n.º 3 (6 de julio de 2020): 2968–72. http://dx.doi.org/10.26452/ijrps.v11i3.2387.
Texto completoChan, S. K., S. K. Lok, G. Wang, Y. Cai, Y. J. Wang, N. Wang y I. K. Sou. "Formation mechanism of nanotrenches induced by mobile catalytic nanoparticles". Applied Physics Letters 92, n.º 18 (5 de mayo de 2008): 183102. http://dx.doi.org/10.1063/1.2912130.
Texto completoSin, Y. K. "Usage of Mobile Application in Assisting Chemical Experiments". Special Issue No.1 1, n.º 1 (1 de julio de 2020): 30–40. http://dx.doi.org/10.33093/ijcm.2020.1.x1.3.
Texto completoTesis sobre el tema "Mobile nanoparticles"
Massasso, Giovanni. "Entrapment of mobile radioactive elements with coordination polymers and supported nanoparticles". Thesis, Montpellier 2, 2014. http://www.theses.fr/2014MON20172/document.
Texto completoNuclear power industry still demands further research to improve the methods for the storage and the confinement of the hazardous radioactive wastes coming from the fission of radionuclide 235U. The volatile radioactive 129I (half-life time 15x107 years) is one of the most critical products coming from the reprocessing plants in the fuel-closed cycles. In the present thesis the family of coordination solid networks, known as Hofmann-type structures, was studied in the form as both bulk and supported nanoparticles for the selective entrapment of the molecular iodine. This set of investigated materials exhibited a general formula M'(L)[M''(CN)4] where M' = NiII or CoII; L = pyrazine, 4,4'-bipyridine, 4,4'-azopyridine; M'' = NiII, PdII or PtII. Initially, the material NiII(pz)[NiII(CN)4] and its analogue structures were precipitated as microcrystalline bulky compounds and fully characterized. The insertion of the iodine in the bulky host structures was performed with different methods: 1) adsorption of iodine in solutions of cyclohexane at room temperature; 2) adsorption of iodine vapours at 80 °C; 3) adsorption of iodine vapours at 80 °C in presence of water steam (for few selected materials). The different methods did not affect the nature of the confined iodine. For the entrapment in solution, results indicated that the Hofmann-type structures NiII(pz)[NiII(CN)4], NiII(pz)[PdII(CN)4] and CoII(pz)[NiII(CN)4] could host one I2 molecule per unit cell. The iodine resulted physisorbed as molecular iodine in interaction with the host structure. GCMC simulations confirmed the maximal capacities and indicated that iodine could interact with both the pyrazine and the coordinated cyanides. Experimentally, however, the modulation of the metals showed a slightly different strength of interaction I2-lattice bringing to a different lattice adaptation. The materials also could be fully regenerated since the complete desorption of iodine occurred before the decomposition of the host structure. Reiterated adsorption-desorption steps (3 cycles) on the networks NiII(pz)[NiII(CN)4] and NiII(pz)[PdII(CN)4] indicated an excellent structural resistance to cycling and a maintained high capacity. A different mechanism of confinement was detected for the structure NiII(pz)[PtII(CN)4] which reacted with iodine giving complex NiII(pz)[PtII/IV(CN)4].I-. Finally, the modulation of the organic ligand L indicated that the replacement of the ligand pyrazine with longer ligands, to obtain larger pores, had a detrimental effect on the maximal iodine loading due to a weaker confinement. After the study of the bulk materials, we considered the preparation of supported nanoparticles of NiII(pz)[NiII(CN)4] for the entrapment of iodine. The nanoparticles were obtained by a step-by-step method, impregnating a set of diammine-grafted mesoporous silicas with the precursors of NiII(pz)[NiII(CN)4]. We detected nanoparticles with mean size 2.8 nm by transmission electronic microscopy. The insertion of iodine in the nanoparticles was confirmed by FT-IR. Thermal treatments indicated that the portion of iodine inside the nanoparticles could be reversibly desorbed in the range 150-250 °C and reintroduced in a cyclic process. It was estimated that the amount of physisorbed iodine in the NPs, with respect to the amount of deposited NPs matched with the maximal capacity NiII(pz)[NiII(CN)4]@I2
Almazrou, Yaser M. "EFFECTS OF MOBILE NANOPARTICLES ON THE MORPHOLOGY AND TOPOGRAPHY OF POLYSULFONE/POLYIMIDE THIN FILMS". University of Akron / OhioLINK, 2018. http://rave.ohiolink.edu/etdc/view?acc_num=akron1531145752009354.
Texto completoDelchet, Carole. "Matériaux hybrides pour la décontamination et le confinement d'éléments mobiles : application au Césium". Thesis, Montpellier 2, 2013. http://www.theses.fr/2013MON20251/document.
Texto completoNuclear industry produced, nowadays, a wide range of liquid radioactive waste containing cesium. Materials based on cyanométallates exhibit a very high affinity for the inclusion of this element in a wide range of pH and a good resistance to ionising radiation which makes them very interesting for decontamination. Every year, at La Hague, several hundred m3 of radioactive waste are treated by a nickel ferrocyanide preformed precipitate in bulk form (PPFeNi, general formula K2xNi2-x [Fe (CN) 6] with 0,5> x> 1,1). This process shows a good decontamination but it's difficult to implement and it produces a sludge that must then be treated by waste channel available.The purpose of this thesis is to find a material for the decontamination of Cs which have a good capacity, selectivity, adapted for continuous decontamination process (column) and compatible with conventional waste (cement or glass). To achieve this goal, we have several objectives:i) The study of solid materials based on cyanometallate to improve knowledge on the mechanism of fixation of cesium on these compounds by varying the nature of transition metal and the presence or not of potassium in the crystal structure,ii) Synthesis of nanocomposites containing cyanometallate nanoparticles incorporated into inorganic matrices which are mesostructured silica and porous glass. Silica is used as a template, whereas the porous glass shaping ball will be used for a decontamination process.Bulk materials containing potassium in the structure present the greater sorption capacity toward Cs. Hybrid materials containing cyanometallate nanoparticles have a lesser absolute capacity than the respective bulk materials, however, based on the amount of sorbent particles, the maximum sorption capacity of hybrid materials is higher than bulk materials. However, the selectivity is comparable for hybrid and bulk materials with a distribution coefficient about 104 to 105 mL.g-1.The performance of the hybrid materials were evaluated on real effluents. These materials are very promising for the decontamination of effluents from a treatment process in column one hand they have a high selectivity towards cesium and despite high salinity of the solution to decontaminate and other formatting (glass beads) adapted to this type of process
Libros sobre el tema "Mobile nanoparticles"
Sinharoy, Arindam y Piet N. L. Lens, eds. Environmental Technologies to Treat Rare Earth Elements Pollution: Principles and Engineering. IWA Publishing, 2022. http://dx.doi.org/10.2166/9781789062236.
Texto completoCapítulos de libros sobre el tema "Mobile nanoparticles"
Lian, Weijie, Qiong Yu, Xiwang Du, Yuxin Zhai, Shuang Li y Lan Ma. "Synthesis of Ag/Ni(OH)2 Catalyst Generated from LDH for the Selective Hydrogenation of Citral". En Advances in Transdisciplinary Engineering. IOS Press, 2022. http://dx.doi.org/10.3233/atde220440.
Texto completo"Fabrication of Mobile Hybrid Microswimmers Using Micro/ Nanoparticles and Bacterial Flagella". En Nanobiomaterials, 379–400. CRC Press, 2013. http://dx.doi.org/10.1201/b15362-18.
Texto completo"Newer Approaches in Phytoremediation". En Nano-Phytoremediation Technologies for Groundwater Contaminates, 145–78. IGI Global, 2020. http://dx.doi.org/10.4018/978-1-5225-9016-3.ch011.
Texto completoChaudhary, Khushboo, Suphiya Khan y Pankaj Kumar Saraswat. "Newer Approaches in Phytoremediation". En Research Anthology on Synthesis, Characterization, and Applications of Nanomaterials, 1785–808. IGI Global, 2021. http://dx.doi.org/10.4018/978-1-7998-8591-7.ch074.
Texto completoActas de conferencias sobre el tema "Mobile nanoparticles"
Rehhagen, Chris, Shanawaz Rafiq, Kyra N. Schwarz, Gregory D. Scholes y Stefan Lochbrunner. "Singlet and Excimer Exciton Diffusion in Perylene Derivative Nanoparticles". En International Conference on Ultrafast Phenomena. Washington, D.C.: Optica Publishing Group, 2022. http://dx.doi.org/10.1364/up.2022.th4a.9.
Texto completoKyung, Amanda, Mia Moon y Yoon Jeong Kwon. "Study on the Biochemical Nanoparticles for Bioimaging and Molecular Diagnostics of Alzheimer's Disease". En 2018 9th IEEE Annual Ubiquitous Computing, Electronics & Mobile Communication Conference (UEMCON). IEEE, 2018. http://dx.doi.org/10.1109/uemcon.2018.8796547.
Texto completoMisajel, Jean Pierre Arce, Sario Angel Chamorro Quijano, Dominick Marco Cruz Esteban, Steve Robert Torres Rojas, Deyby Huamanchahua y Ruth Aracelis Manzanares Grados. "Design of a Prototype for Water Desalination Plant using Flexible, Low-Cost Titanium Dioxide Nanoparticles". En 2021 IEEE 12th Annual Ubiquitous Computing, Electronics & Mobile Communication Conference (UEMCON). IEEE, 2021. http://dx.doi.org/10.1109/uemcon53757.2021.9666586.
Texto completoRam, Vineetha, VISHNU KAVUNGAL, Pradeep Chandran y Nampoori Vadakkedathu Parameswaran Narayana. "Silver Nanoparticles as Radiation Absorbers to Reduce the Effect of Mobile Phone Radiation on DNA". En International Conference on Fibre Optics and Photonics. Washington, D.C.: OSA, 2012. http://dx.doi.org/10.1364/photonics.2012.w3b.3.
Texto completoRickard, Ashlyn G., Christopher A. DeRosa, Cassandra L. Fraser y Gregory M. Palmer. "The Development of an In Vivo Mobile Dynamic Microscopy System that Images Cancerous Tumors via Fluorescent and Phosphorescent Nanoparticles". En Optical Molecular Probes, Imaging and Drug Delivery. Washington, D.C.: OSA, 2017. http://dx.doi.org/10.1364/omp.2017.omm4d.3.
Texto completoGazeau, Florence, Michael Lévy y Claire Wilhelm. "Intracellular Confinement of Magnetic Nanoparticles by Living Cells: Impact for Imaging and Therapeutic Applications". En MAGNETIC RESONANCE IN POROUS MEDIA: Proceedings of the 10th International Bologna Conference on Magnetic Resonance in Porous Media (MRPM10), including the 10th Colloquium on Mobile Magnetic Resonance (CMMR10). AIP, 2011. http://dx.doi.org/10.1063/1.3562223.
Texto completoKumar, Anand y Anchu Ashok. "Catalytic Decomposition of Ethanol over Bimetallic Nico Catalysts for Carbon Nanotube Synthesis". En Qatar University Annual Research Forum & Exhibition. Qatar University Press, 2020. http://dx.doi.org/10.29117/quarfe.2020.0039.
Texto completoOzeh, Michael y A. G. Agwu Nnanna. "Waste Heat Recovery for Powering Mobile Devices Using Thermoelectric Generators and Evaporatively-Cooled Heat Sink". En ASME 2018 International Technical Conference and Exhibition on Packaging and Integration of Electronic and Photonic Microsystems. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/ipack2018-8354.
Texto completoErickson, David. "Optofluidics for Mobile Health, Bioenergy, and Nanoparticle Analysis". En CLEO: Science and Innovations. Washington, D.C.: OSA, 2014. http://dx.doi.org/10.1364/cleo_si.2014.sth3h.1.
Texto completoYinon, Lital, Nickolas J. Themelis y V. Faye McNeill. "Ultrafine Particles From WTE and Other Combustion Sources". En 18th Annual North American Waste-to-Energy Conference. ASMEDC, 2010. http://dx.doi.org/10.1115/nawtec18-3581.
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