Ĭhen L, Huang B, Qiu X, Wang X, Luque R, Li Y (2016) Seed-mediated growth of MOF-encapsulated core-shell nanoparticles: toward advanced room temperature nanocatalysts. īele M, Jovanovic P, Pavlisic A et al (2014) A highly active PtCu 3 intermetallic core-shell, multilayered Pt-skin, carbon embedded electrocatalyst produced by a scale-up sol–gel synthesis. Zhao F, Chen X, Zhang J et al (2021) A wearable, nozzle-diffuser microfluidic pump based on high-performance ferroelectric nanocomposites. Zhang J, Zhao F-w, Liu Z-h et al (2021) Influence of core–shell structured conductive fillers on the electromechanical properties of ferroelectric nanocomposites. Zhang J, Zhao F, Zuo Y-j et al (2020) Improving actuation strain and breakdown strength of dielectric elastomers using core-shell structured CNT-Al 2O 3. Ghosh Chaudhuri R, Paria S (2011) Core/shell nanoparticles: classes, properties, synthesis mechanisms, characterization, and applications. Microporous Mesoporous Mater 242:136–143. Rajabi SK, Sohrabnezhad S (2017) Synthesis and characterization of magnetic core with two shells: mordenite zeolite and CuO to form Fe 3O core-shell-as a visible light driven photocatalyst. Īrnal PM, Comotti M, Schüth F (2006) High-temperature-stable catalysts by hollow sphere encapsulation. Li G, Tang Z (2014) Noble metal oxide core/yolk-shell nanostructures as catalysts: recent progress and perspective. Liu Y, Tang Z (2013) Multifunctional core-shell nanostructures. Īric BP, Scrosati B, Tarascon J-M, Schalkwijk W (2005) Nanostructured materials for advanced energy conversion and storage devices. Moriarty P (2001) Nanostructured materials. Ghosh Chaudhuri R, Paria S (2012) Core/shell nanoparticles: classes, properties, synthesis mechanisms, characterization, and applications. Finally, the article offers the future prospective application of the core–shell nanomaterials to envision that new breakthrough will be yield in this field. This paper makes a comprehensive analysis and discussion on the considerable and representative research in each field, in order to provide the reference for the relevant research works by taking the advantages of structural stability and high dispersive active phases of core–shell materials. This review emphasizes their applications in terms of five major fields: catalysis, adsorption, sensing, membrane separation and biomedical application, which render them promising candidates for diverse practical manipulations such as environmental remediation, gas separation and storage, flexible electronic devices and therapeutic vehicles. Recently, the core–shell nanostructured materials have gained considerable attention due to their nano-scale size effect, well-controlled structure, and tunable physicochemical features which extend their applications in many hot research topics.
0 Comments
Leave a Reply. |