Prussian blue modified Fe3O4 nanoparticles for Cs detoxification

Journal of Materials Science

Volumn 49, Issue 20, 2014, Pages 7014-7022

  Arun, T ^a   Justin Joseyphus, R ^a  

^a NATIONAL INSTITUTE OF TECHNOLOGY   (India)

Author keywords

[No Author keywords available]

Indexed keywords

DETOXIFICATION; METAL IONS; NANOPARTICLES; TRANSMISSION ELECTRON MICROSCOPY;

ADSORPTION KINETICS; ADSORPTION RATES; APPLIED MAGNETIC FIELDS; CAPTURE EFFICIENCY; PRUSSIAN BLUE MODIFIED FE; PSEUDO-FIRST-ORDER KINETIC MODELS; REMOVAL EFFICIENCIES; SURFACE-MODIFIED;

CESIUM;

EID: 84905669736     PISSN: 00222461     EISSN: 15734803     Source Type: Journal    
DOI: 10.1007/s10853-014-8406-x     Document Type: Article

References (53)

1. Avery SV (1996) Fate of caesium in the environment: distribution between the abi-otic and biotic components of aquatic and terrestrial ecosystems. J Environ Radioact 30:139-171
2. Faustino PJ, Yang Y, Progar JJ, Brownell CR, Sadrieh N, May JC, Leutzinger E et al (2008) Quantitative determination of cesium binding to ferrichexacyanoferrate: Prussian blue. J Pharm Biomed 47:114-125
3. Pearce J (1994) Studies of any toxicological effects of Prussian blue compounds in mammals - A review. Food Chem Toxicol 32:577-582
4. Hu M, Furukawa S, Ohtani R, Sukegawa H, Nemoto Y, Reboul J, Kitagawa S, Yamauchi Y (2012) Synthesis of Prussian blue nanoparticles with a hollow interior by controlled chemical etching. Angew Chem Int Ed 51:984-988
5. Lian HY, Hu M, Liu CH, Yamauchi Y, Wu KCW (2012) Highly biocompatible, hollow coordination polymer nanoparticles as cisplatin carriers for efficient intracellular drug delivery. Chem Commun 48:5151-5153
6. Hu M, Belik A, Imura M, Mibu K, Tsujimoto Y, Yamauchi Y (2012) Synthesis of superparamagnetic nanoporous iron oxide particles with hollow interiors by using Prussian blue coordination polymers. Chem Mater 24:2698-2707
7. Chiang YD, Hu M, Kamachi Y, Ishihara S, Takai K, Tsujimoto Y, Ariga K, Wu KCW, Yamauchi Y (2013) Rational design and synthesis of cyano-bridged coordination polymers with precise control of particle size from 20 to 500 nm. Eur J Inorg Chem 2013:3141-3145
8. Hu M, Ishihara S, Ariga K, Imura M, Yamauchi Y (2013) Kinetically controlled crystallization for synthesis of monodispersed coordination polymer nanocubes and their self-assembly to periodic arrangements. Chem Eur J 19:1882-1885
9. Hu M, Belik AA, Imura M, Yamauchi Y (2013) Tailored design of multiple nanoarchitectures in metal-cyanide hybrid coordination polymers. J Am Chem Soc 135:384-391
10. Hu M, Yamauchi Y (2011) Synthesis of a titanium-containing Prussian-blue analogue with a well-defined cube structure and its thermal conversion into a nanoporous titanium-iron-based oxide. Chem Asian J 6:2282-2286
11. Thompson DF, Church CO (2001) Prussian blue for treatment of radiocesium poisoning. Pharmacotherapy 21:1364-1367
12. Barton GB, Hepworth JL, McClanahan ED, Moore RL, VanTuyl HH (1958) Chemical processing wastes, recovering fission products. Ind Eng Chem 50:212-216
13. + adsorption via lattice defect sites of Prussian blue filled with coordination and crystallization water molecules. Dalton Trans 42:16049-16055
14. Namiki Y, Namiki T, Ishii Y, Koido S, Nagase Y, Tsubota A, Tada N, Kitamoto Y (2012) Inorganic-organic magnetic nanocomposites for use in preventive medicine: a rapid and reliable elimination system for cesium. Pharm Res 29:1404-1418
15. Sangvanich T, Sukwarotwat V, Wiacek RJ, Grudzien RM, Fryxell GE, Addleman RS, Timchalk C, Yantasee W (2010) Selective capture of cesium and thallium from natural waters and simulated wastes with copper ferrocyanide functionalized mesoporous silica. J Hazard Mater 182:225-231
16. Delchet C, Tokarev A, Dumail X, Toquer G, Barre Y, Guari Y, Guerin C, Larionova J, Grandjean A (2012) Extraction of radioactive cesium using innovative functionalized porous materials. RSC Adv 2:5707-5716
17. Lin Y, Fryxell GE, Wu H, Englhard M (2001) Selective sorption of cesium using self-assembled monolayers on mesoporous supports. Environ Sci Technol 35:3962-3966
18. Parab H, Sudersanan M (2010) Engineering a lignocellulosic biosorbent-Coir pith for removal of cesium from aqueous solutions: equilibrium and kinetic studies. Water Res 44:854-860
19. Chang CY, Chau LK, Hu WP, Wang CY, Liao JH (2008) Nickel hexacyanoferrate multilayers on functionalized mesoporous silica supports for selective sorption and sensing of cesium. Microporous Mesoporous Mat 109:505-512
20. Rassat SD, Sukamto JH, Orth RJ, Lilga MA, Hallen RT (1999) Development of an electrically switched ion exchange process for selective ion separations. Sep Purif Technol 15:207-222
21. Lilga MA, Orth RJ, Sukamto JPH, Rassat SD, Genders JD, Gopal R (2001) Cesium separation using electrically switched ion exchange. Sep Purif Technol 24:451-466
22. Chen BW, Xia XH (2007) Highly stable nickel hexacyanoferrate nanotubes for electrically switched ion exchange. Adv Funct Mater 17:2943-2948
23. Lilga MA, Orth RJ, Sukamto JPH, Haight SM, Schwartz DT (1997) Metal ion separations using electrically switched ion exchange. Sep Purif Technol 11:147-158
24. Chen R, Tanaka H, Kawamoto T, Asai M, Fukushima C, Kurihara M, Watanabe M, Arisaka M, Nankawa T (2012) Preparation of a film of copper hexacyanoferrate nanoparticles for electrochemical removal of cesium from radioactive wastewater. Electrochem Commun 25:23-25
25. Prout WE, Russell ER, Grob HJ (1965) Ion exchange absorption of cesium by potassium hexacyanocobalt (II) ferrate (II). J Inorg Nucl Chem 27:473-479
26. Chen H, Kaminski MD, Rosengart AJ (2008) 2D modeling and preliminary in vitro investigation of a prototype high gradient magnetic separator for biomedical applications. Med Eng Phys 30:1-8
27. Falkenhagen D, Brandl M, Hartmann J, Kellner KH, Posnicek T, Weber V (2006) Fluidized bed adsorbent systems for extracorporeal liver support. Ther Apher Dial 10:154-159
28. Brandl M, Mayer M, Hartmann J, Posnicek T, Fabian C, Falkenhagen D (2010) Theoretical analysis of ferromagnetic microparticles in streaming liquid under the influence of external magnetic forces. J Magn Magn Mater 322:2454-2464
29. Berry CC, Curtis ASG (2003) Functionalisation of magnetic nanoparticles for applications in biomedicine. J Phys D 36:R198-R206
30. Iacob G, Rotariu O, Strachan NJC, Häfeli UO (2004) Magnetizable needles and wires-modeling an efficient way to target magnetic microspheres in vivo. Biorheology 41:599-612
31. Ritter JA, Ebner AD, Daniel KD, Stewart KL (2004) Application of high gradient magnetic separation principles to magnetic drug targeting. J Magn Magn Mater 280:184-201
32. Aviles MO, Ebner AD, Chen H, Rosengart AJ, Kaminski MD, Ritter JA (2005) Theoretical analysis of a transdermal ferromagnetic implant for retention of magnetic drug carrier particles. J Magn Magn Mater 293:605-615
33. Chen H, Ebner AD, Kaminski MD, Rosengart AJ, Ritter JA (2005) Analysis of magnetic drug carrier particle capture by a magnetizable intravascular stent - 2: parametric study with multi-wire two-dimensional model. J Magn Magn Mater 293:616-632
34. Tang SCN and Lo (2013) IMC Magnetic nanoparticles: essential factors for sustainable environmental applications. Water Res 47:2613-2632
35. Arun T, Prakash K, Justin Joseyphus R (2013) Synthesis and magnetic properties of prussian blue modified Fe nanoparticles. J Magn Magn Mater 345:100-105
36. 4 nanocubes. J Phys Chem Solids 74:1761-1768
37. Kaye SS, Long JR (2007) The role of vacancies in the hydrogen storage properties of Prussian blue analogues. Catal Today 120:311-316
38. Kaye SS, Long JR (2005) Hydrogen storage in the dehydrated Prussian blue analogues M3[Co(CN)6]2 (M = Mn, Fe Co, Ni, Cu, Zn). J Am Chem Soc 127:6506-6507
39. Ming H, Torad NLK, Chiang YD, Wu KCW, Yamauchi Y (2012) Size-and shape-controlled synthesis of Prussian blue nanoparticles by a polyvinylpyrrolidone-assisted crystallization process. Cryst Eng Comm 14:3387-3396
40. Song C, Du JP, Zhao JH, Feng SA, Du GX, Zhu ZP (2009) Hierarchical porous core- shell carbon nanoparticles. Chem Mater 21:1524-1530
41. Cho W, Lee HJ, Oh M (2008) Growth-controlled formation of porous coordination polymer particles. J Am Chem Soc 130:16943-16946
42. Kobler J, Bein T (2008) Porous thin films of functionalized mesoporous silica nanoparticles. ACS Nano 2:2324-2330
43. Sing KSW, Everett DH, Haul RAW, Moscou L, Pierotti RA, Rouquerol J, Siemieniewska T (1985) Reporting physisorption data for gas/solid systems with special reference to the determination of surface area and porosity. Pure Appl Chem 57:603-619
44. Kruk M, Jaroniec M (2001) Gas adsorption characterization of ordered organic-inorganic nanocomposite materials. Chem Mater 13:3169-3183
45. Kim JO, Lee SM, Jeon C (2014) Adsorption characteristics of sericite for cesium ions from an aqueous solution. Chem Eng Res Des. doi: 10.1016/j.cherd.2013.07.020
46. Lv K, Xiong LP, Luo YM (2013) Ion exchange properties of cesium ion sieve based on zirconium molybdopyrophosphate. Colloids Surf A 433:37-46
47. Torad NL, Hu M, Imura M, Naito M, Yamauchi Y (2012) Large Cs adsorption capability of nanostructured Prussian blue particles with high accessible surface areas. J Mater Chem 22:18261-18267
48. Lagergren S (1898) Zurtheorie der sogenannten adsorption gelösterstoffe. K Sven Vetenskapsakad Handl 24:1-39
49. Ho YS, McKay G (1999) Pseudo-second-order model for sorption processes. Process Biochem 34:451-465
50. Thammawong C, Opaprakasit P, Tangboriboonrat P, Sreearunothai P (2013) Prussian blue modified magnetic oxide nanoparticles for removal of cesium from contaminated environment. J Nanopart Res 15:1689-1699
51. Furlani EP, Ng KC (2006) Analytical model of magnetic nanoparticle transport and capture in the microvasculature. Phys Rev 73:061919-1-06191910
52. Tang W, Su Y, Li Q, Gao S, Shang JK (2013) Superparamagnetic magnesium ferrite nanoadsorbent for effective arsenic (III, V) removal and easy magnetic separation. Water Res 47:3624-3634
53. Shan C, Tong M (2013) Efficient removal of trace arsenite through oxidation and adsorption by magnetic nanoparticles modified with Fe-Mn binary oxide. Water Res 47:3411-3421