شماره 46 - بهار 1396
ICNS7
شماره 47-تابستان 1396
فهرست

نانورتل ها: معرفی، ساختار، ویژگی ها، سنتز و کاربردها

نشریه: شماره 43- تابستان 1395 - مقاله 6   صفحات :  43 تا 47



کد مقاله:
43-06

مولفین:
سید حمید احمدی: پژوهشکاه شیمی و مهندسی شیمی ایزان - شیمی
فاطمه پوربهمن


چکیده مقاله:

در دهه های اخیر پیشرفت های چشمگیر در علم نانو منجر به ایجاد ساختارهای پیچیده متنوعی گردیده است. این ساختار های پیچیده شکل های متنوع و در نتیجه ویژگی های متفاوتی را ارائه می نمایند. نمونه ای از این ترکیبات نانو رتل ها با خاصیت ها و کاربرد های منحصر به فرد در صنعت و پزشکی زیستی می باشند. نانو رتل ها از هسته، پوسته و فضای خالی تشکیل شده اند که فضای خالی محیط همگنی را برای کپسولی شدن هسته فراهم می نماید. در این مقاله دید جامعی از روش های ساخت، ساختمان نانو رتل ها و کاربر دهای آن ها ارائه می گردد.


Article's English abstract:

abstract


کلید واژگان:
نانو رتل ها، هسته- پوسته، چند عاملی، هسته متحرک

English Keywords:
english keyword

منابع:
farsi

English References:
1. Y, Shirai; AJ, Osgood; Y, Zhao; KF, Kelly; JM, Tour; Directional Control in Thermally DrivenSingle-Molecule Nanocars. Nano Letters 5 (11):2330-2334, 1. R. P, Feynman; There's Plenty of Room at the Bottom. Engineering and Science 23 (5):22-36, 1960. 2. C. Toumey; Plenty of room, plenty of history. Nature Nanotechnology 4 (12): 783 – 784, 2009. 3. J. Liu, J. Cheng, R. Che, J. Xu, M. Liu, Z. Liu, J. Double-Shelled Yolk–Shell Microspheres with Fe3O4 Cores and SnO2 Double Shells as High-Performance Microwave Absorbers. The Journal of Physical Chemistry C 117 (1): 489 –495, 2013. 4. S.-H. Hu; X. Gao; Nanocomposites with spatially separated functionalities for combined imaging and magnetolytic therapy. Journal of the American Chemical Society 132 (21): 7234 – 7237, 2010. 5. Y. S. Lin; S. H. Wu; C. T. Tseng; Y. Hung; C. Chang; C. Y. Mou; Synthesis of hollow silica nanospheres with a microemulsion as the template. Chemical Communication, 24 (3):3542–3544, 2009. 6. P. M. Arnal; M. Comotti; F. Sch_th; High-temperature-stable catalysts by hollow sphere encapsulation. Angewandte Chemie International Edition in English, 45 (48):8224 -8227, 2006. 7. V. Montes-García; J. Pérez-Juste; I. Pastoriza-Santos; L.M. Liz-Marzán; Metal Nanoparticles and Supramolecular Macrocycles. Chemistry - A European Journal, 20 ( 35):10874-10883, 2014. 8. L. Li; F. Tang; H. Liu; T. Liu; N. Hao; D. Chen; X. Teng; J. He; In vivo delivery of silica nanorattle encapsulated docetaxel for liver cancer therapy with low toxicity and high efficacy. ACS Nano, 4 (11):6874–6882, 2010. 9. Q. Xie; J. Li; Q. Tian; R. Shi; Template-free synthesis of zinc citrate yolk-shell microspheres and their transformation to ZnO yolk-shell nanospheres.Journal of Materials Chemistry, 22 (27):13541–13547, 2012. 10. Q. Zhang; J. Ge; J. Goebl; Y. Hu; Z. Lu; Y. Yin; Rattle-type silica colloidal particles prepared by a surface-protected etching process. Nano Research, 2 (7):583-591, 2010. 11. X. Huang; C. Guo; J. Zuo; N. Zheng; G. D. Stucky; An Assembly Route to Inorganic Catalytic Nanoreactors Containing Sub?10?nm Gold Nanoparticles with Anti?Aggregation Properties Small, 5 (3):361–365, 2009. 12. A. D. Pandey; R. Gu; M. Leoni; F. Schu; C. Weidenthaler; Influence of the Microstructure of Gold?Zirconia Yolk?Shell Catalysts on the CO Oxidation Activity. The Journal of Physical Chemistry C, 114 (45):19386–19394, 2010. 13. C. Galeano; R. Güttel; M. Paul; P. Arnal; A.-H. Lu; F. Schüth; Yolk?Shell Gold Nanoparticles as Model Materials for Support?Effect Studies in Heterogeneous Catalysis: Au,@ C and Au,@ ZrO2 for CO Oxidation as an Example. Chemistry–A European Journal, 17 (30):8434–8439, 2011. 14. J. Liu; S. Z. Qiao; S. Budi Hartono; G. Q. M. Lu; Monodisperse Yolk-Shell Nanoparticles with a Hierarchical Porous Structure for Delivery Vehicles and Nanoreactors. Angew. Chem. Int. Ed., 49 (29):4981–4985, 2010. 15. C.-C. Huang; W. Huang; C.-S. Yeh; Shell-by-shell synthesis of multi-shelled mesoporous silica nanospheres for optical imaging and drug delivery. Biomaterials, 32 (2):556–564, 2011. 16. N. Liu; Z. Lu; J. Zhao; M. T. McDowell; H.-W. Lee; W. Zhao; Y. Cui; A pomegranate-inspired nanoscale design for large-volume-change lithium battery anodes. Nature nanotechnology., 9 (3): 187–192, 2014. 17. X. Zhou; J. Tang; J. Yang; J. Xie; L. Ma; Silicon@carbon hollow core–shell heterostructures novel anode materials for lithium ion batteries. Electrochim. Acta, 87:663–668, 2013. 18. R. Purbia; S. Paria; Yolk/Shell Nanoparticles: Classifications, Synthesis, Properties, and Applications. Nanoscale, 7:19789-19873, 2015. 19. M. Priebe; K. M. Fromm, Nanorattles or Yolk–Shell Nanoparticles—What Are They, How Are They Made, and What Are They Good For? Chemistry: A European Journal, 21 (10):3854 – 3874, 2015. 20. K. Zhang; H. Chen; Y. Zheng; Y. Chen; M. Ma; X. Wang; L. Wang; D. Zeng; J. Shi; A facile in situ hydrophobic layer protected selective etching strategy for the synchronous synthesis/modification of hollow or rattle-type silica nanoconstructs. Journal of Materials Chemistry, 22 (25):12553 –12561, 2012. 21. B. Liu; J. Wang; S. Sun; X. Wang; M. Zhao; W. Zhang; H. Zhang; X. Yang; A general method for the synthesis of various rattle-type microspheres and their diverse applications. Rsc Advances., 3 (40):18506–18518, 2013. 22. H. Grçger; F. Gyger; P. Leidinger; C. Zurm_hl; C. Feldmann; Microemulsion Approach to Nanocontainers and Its Variability in Composition and Filling. Advanced Material., 21 (16):1586–1590, 2009. 23. H. C. Zeng; Ostwald Ripening: A Synthetic Approach for Hollow Nanomaterials. Current Nanoscience, 3 (2):77–181, 2007. 24. B. Liu; H. C. Zeng; Symmetric and Asymmetric Ostwald Ripening in the Fabrication of Homogeneous Core–Shell Semiconductors. Small, 1 (5):566–571, 2005. 25. D. S. Jung; Y. N. Ko; Y. C. Kang; S. B. Park; Yolk–shell structured Gd2O3:Eu3 phosphor prepared by spray pyrolysis: the effect of preparation conditions on microstructure and luminescence propertyes. Physical Chemistry Chemical Physics, 17 (2) 1325-1331, 2015. 26. J. H. Bang; K. S. Suslick; Applications of Ultrasound to the Synthesis of Nanostructured Material Advanced Materials., 22 (10):1039–1059, 2010. 27. G. Song; C. Li; J. Hu; R. Zou; K. Xu; L. Han; Q. Wang; J. Yang; Z. Chen; Z. Qin; A simple transformation from silica core–shell–shell to yolk–shell nanostructures: a useful platform for effective cell imaging and drug delivery. Journal of Materials Chemistry, 22 (33):17011– 17018, 2012 28. H. Wu; G. Liu; S. Zhang; J. Shi; L. Zhang; Y. Chen; F. Chen; H. Chen; Biocompatibility, MR imaging and targeted drug delivery of a rattle-type magnetic mesoporous silica nanosphere system conjugated with PEG and cancer-cell-specific ligands. Journal of Materials Chemistry., 21 (9):3037–3045, 2011. 29. C. Chen, X. Fang, B. Wu, L. Huang, N. Zheng, A Multi?Yolk–Shell Structured Nanocatalyst Containing Sub?10 nm Pd Nanoparticles in Porous CeO2. Chem. Cat. Chem., 4 (10):1578–1586, 2012. 30. M. S. Whittingham; Lithium Batteries and Cathode Materials. Chemical Review., 104 (10):4271–4302, 2010. 31. N. Liu, H. Wu, M. T. McDowell, Y. Yao, C. Wang, Y. Cui, A Yolk-Shell Design for Stabilized and Scalable Li-Ion Battery Alloy Anodes. Nano letters 12 (6):3315–3321, 2012. 32. T. Zeng, X. Zhang, Y. Ma, S. Wang, H. Niu, Y. Cai, A functional rattle-type microsphere with a magnetic-carbon double-layered shell for enhanced extraction of organic targets. Chemical Communications, 49 (54):6039–6041, 2013. .



فایل مقاله
تعداد بازدید: 509
تعداد دریافت فایل مقاله : 21



طراحی پرتال|طراحی پورتالطراحی پرتال (طراحی پورتال): آرانا نتورک