Optimized solvent-exchange synthesis method for C60 colloidal dispersions

Maples, Randall D.; Hilburn, Martha E; Murdianti, Befrika S.; Koralege, Rangika S. Hikkaduwa; Williams, Jason S.; Kuriyavar, Satish I.; Ausman, Kevin D.

doi:10.1016/j.jcis.2011.12.060

Cited by 20 publications

(16 citation statements)

References 26 publications

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“…Derivatization and solubilization have been disregarded in this field. The most relevant techniques of AFD preparation are solvent exchange [11,14,15], dialysis [16], and mixing [17][18][19]. However, the total yield of fullerene transfer into water of 100 % has not yet been achieved, which leads to significant losses and increases for the cost of the final product, especially for EMFs.…”

Section: Introductionmentioning

confidence: 99%

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Optimization of the solvent-exchange process for high-yield synthesis of aqueous fullerene dispersions

Mikheev¹,

Pirogova²,

Bolotnik³

et al. 2018

Nanosystems: Phys. Chem. Math.

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The ultrasound-assisted solvent-exchange technique for aqueous fullerene dispersions (AFD) of C 60 (10 −4 -10 −6 M) have been improved for high-yield synthesis, thereby achieving AFDs with total recovery over 90 %. Using ICP-AES, HPLC-UV, HGC-MS, the elemental and residual organic compounds have been estimated as not exceeding 3 ppm. The possible structure of fullerene clusters in AFD was assumed as {n[C 60 ]mC 6 H 5 COO − (m − x)Na + }xNa + .

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Section: Introductionmentioning

confidence: 99%

“…Apart from the yield, the main drawback for the solvent-exchange process is significant amounts of hazardous organic substances in AFDs [11,14,15]. However, not much attention is paid to the purity of the produced dispersions, which is unacceptable for biomedicine.…”

Section: Introductionmentioning

confidence: 99%

Optimization of the solvent-exchange process for high-yield synthesis of aqueous fullerene dispersions

Mikheev¹,

Pirogova²,

Bolotnik³

et al. 2018

Nanosystems: Phys. Chem. Math.

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“…Various other solvents have been used with or without THF for the production of sub-100 nm low dimensional C 60 nanoclusters. Other examples can be found elsewhere 37,38 . Recently Park et al 39 investigated the critical effect of solvent geometry on the morphology of C 60 prepared by a drop-drying process at room temperature.…”

Section: Nanostructured Crystalline Fullerenesmentioning

confidence: 98%

Self-Assembled Fullerene Nanostructures

Shrestha¹,

Shrestha²,

Hill³

et al. 2013

J. Oleo Sci.

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“…Several literature reports indicate that when a solvent-exchange method is used to prepare nC 60 , the type of solvent used during the preparation could affect the size, stability, and surface chemistry of nC 60 [8,22,23]. We hypothesize that the types of solvents and the detailed routes involved in the preparation of nC 60 may have even greater effects on the aggregation and thus pore structures of nC 60 and that this subsequently affects nC 60 -contaminant interactions.…”

Section: Introductionmentioning

confidence: 94%

Contaminant‐mobilizing capability of fullerene nanoparticles (nC₆₀): Effect of solvent‐exchange process in nC₆₀ formation

Wang

Fortner

Hou

et al. 2012

Enviro Toxic and Chemistry

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Abstract-Fullerene nanoparticles (nC 60 ) in aqueous environments can significantly enhance the transport of hydrophobic organic contaminants by serving as a contaminant carrier. In the present study, the authors examine the effect of the solvent-exchange process on nC 60 aggregate formation and, subsequently, on nC 60 's contaminant-mobilizing capability. A series of nC 60 samples were prepared using a modified toluene-water solvent-exchange method through the inclusion of a secondary organic solvent in the phase transfer of molecular C 60 in toluene to nC 60 in water. Two groups of solvents-a water-miscible group and a non-water-miscible group-of varied polarity were selected as secondary solvents. The involvement of a secondary solvent in the phase transfer process had only small effects on the particle size and distribution, z potential, and mobility of the nC 60 products but significantly influenced the capability of nC 60 to enhance the transport of 2,2 0 ,5,5 0 -polychlorinated biphenyl (PCB) in a saturated sandy soil column, regardless of whether the secondary solvent was water-miscible or non-water-miscible. The two groups of secondary solvents appear to affect the aggregation properties of nC 60 in water via different mechanisms. In general, nC 60 products made with a secondary water-miscible solvent have stronger capabilities to enhance PCB transport. Taken together, the results indicate that according to formation conditions and solvent constituents, nC 60 will vary significantly in its interactions with organic contaminants, specifically as related to adsorption or desorption as well as transport in porous media. Environ. Toxicol. Chem. 2013;32:329-336. # 2012 SETAC

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Optimized solvent-exchange synthesis method for C60 colloidal dispersions

Cited by 20 publications

References 26 publications

Optimization of the solvent-exchange process for high-yield synthesis of aqueous fullerene dispersions

Optimization of the solvent-exchange process for high-yield synthesis of aqueous fullerene dispersions

Self-Assembled Fullerene Nanostructures

Contaminant‐mobilizing capability of fullerene nanoparticles (nC₆₀): Effect of solvent‐exchange process in nC₆₀ formation

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Optimized solvent-exchange synthesis method for C60 colloidal dispersions

Cited by 20 publications

References 26 publications

Optimization of the solvent-exchange process for high-yield synthesis of aqueous fullerene dispersions

Optimization of the solvent-exchange process for high-yield synthesis of aqueous fullerene dispersions

Self-Assembled Fullerene Nanostructures

Contaminant‐mobilizing capability of fullerene nanoparticles (nC60): Effect of solvent‐exchange process in nC60 formation

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Product

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Contaminant‐mobilizing capability of fullerene nanoparticles (nC₆₀): Effect of solvent‐exchange process in nC₆₀ formation