Characterisation and determination of fullerenes: A critical review

Astefanei, Alina; Núñez, Óscar; Galcerán, M.T.

doi:10.1016/j.aca.2015.03.025

Cited by 153 publications

(64 citation statements)

References 153 publications

(391 reference statements)

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“…Namely, although LC-MS methods are a powerful tool for the quantization of fullerenes in complex samples, these techniques alone cannot provide detailed qualitative information. 25 Due to the presence of six malonic addends on the C 60 skeleton, one may expect that the number of -OH groups will be smaller than in the case of pure fullerenol (i.e., 26). 19 Furthermore, the presence of residual water molecules and possible partial decarboxylation 9 additionally increases uncertainty of the molecular mass calculations from the measured hydrogen quantity.…”

Section: Resultsmentioning

confidence: 99%

Basic hydrolysis of fullerene-based esters: a tiny step away from nucleophilic addition to fullerene

Cerar

Cerkovnik

2015

ACSi

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Direct nucleophilic addition of -OH groups on the C 60 skeleton in the basic hydrolysis of ethyl ester of T h -symmetric fullerenehexamalonic acid (T h -FHMA), leading to the formation of a hybrid with features of T h -FHMA and fullerenol, has been observed as an important side reaction. The hydroxylation takes place at considerably milder conditions as those usually used in the synthesis of C 60 fullerenols. UV/Vis and IR spectroscopy were successfully used as a fast monitoring tool which might be of help also in other investigations where additions on C 60 skeleton of molecules with distinct absorption spectra take place.

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Section: Resultsmentioning

confidence: 99%

Basic hydrolysis of fullerene-based esters: a tiny step away from nucleophilic addition to fullerene

Cerar

Cerkovnik

2015

ACSi

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“…[8][9][10][11][12][13][14] While in low-polar aromatic solvents, fullerenes are well solvated and relatively well dissolved, 14,15 in water they generate hydrosols and suspensions. 5,11,[16][17][18][19][20][21][22][23][24][25][26][27][28][29][30] In highly polar organic solvents, the molecular solubility of fullerenes is negligible, 14,15 but they readily form colloidal solutions. [9][10][11][12][13][14][31][32][33][34][35] The state of fullerenes, either molecular or colloidal, in the so-called 'good' or 'strong' solvents, such as CS 2 , toluene, and benzene, is still a matter of discussion.…”

Section: Introductionmentioning

confidence: 99%

Towards better understanding of C₆₀organosols

Mchedlov‐Petrossyan

Kamneva

Al-Shuuchi

et al. 2016

Phys. Chem. Chem. Phys.

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“…A number of nanomaterials have been explored for use as supports and stationary phases in column, capillary or planar LC methods. As is indicated in Table , both carbon‐based nanomaterials and inorganic nanomaterials have been used in LC applications . Much of this work was been done through the use of columns, however, nanomaterials have also been employed in packed capillaries and in planar techniques such as thin‐layer chromatography (TLC) and ultrathin‐layer chromatography (UTLC) (see Sections –).…”

Section: Types Of Nanomaterials Used In Lcmentioning

confidence: 99%

“…The figures shown for the inorganic nanomaterials are (top) nanostructured columns coated with a material such as aluminum oxide and (bottom) gold nanoparticles coated on graphene‐modified silica. These figures were adapted with permission from .…”

Section: Types Of Nanomaterials Used In Lcmentioning

confidence: 99%

Nanomaterials as stationary phases and supports in liquid chromatography

et al. 2017

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The development of various nanomaterials over the last few decades has led to many applications for these materials in liquid chromatography (LC). This review will look at the types of nanomaterials that have been incorporated into LC systems and the applications that have been explored for such systems. A number of carbon-based nanomaterials and inorganic nanomaterials have been considered for use in LC, ranging from carbon nanotubes, fullerenes and nanodiamonds to metal nanoparticles and nanostructures based on silica, alumina, zirconia and titanium dioxide. Many ways have been described for incorporating these nanomaterials into LC systems. These methods have included covalent immobilization, adsorption, entrapment, and the synthesis or direct development of nanomaterials as part of a chromatographic support. Nanomaterials have been used in many types of LC. These applications have included the reversed-phase, normal-phase, ion-exchange, and affinity modes of LC, as well as related methods such as chiral separations, ion-pair chromatography and hydrophilic interaction liquid chromatography. Both small and large analytes (e.g., dyes, drugs, amino acids, peptides and proteins) have been used to evaluate possible applications for these nanomaterial-based methods. The use of nanomaterials in columns, capillaries and planar chromatography has been considered as part of these efforts. Potential advantages of nanomaterials in these applications have included their good chemical and physical stabilities, the variety of interactions many nanomaterials can have with analytes, and their unique retention properties in some separation formats.

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Characterisation and determination of fullerenes: A critical review

Cited by 153 publications

References 153 publications

Basic hydrolysis of fullerene-based esters: a tiny step away from nucleophilic addition to fullerene

Basic hydrolysis of fullerene-based esters: a tiny step away from nucleophilic addition to fullerene

Towards better understanding of C₆₀organosols

Nanomaterials as stationary phases and supports in liquid chromatography

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Characterisation and determination of fullerenes: A critical review

Cited by 153 publications

References 153 publications

Basic hydrolysis of fullerene-based esters: a tiny step away from nucleophilic addition to fullerene

Basic hydrolysis of fullerene-based esters: a tiny step away from nucleophilic addition to fullerene

Towards better understanding of C60organosols

Nanomaterials as stationary phases and supports in liquid chromatography

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Towards better understanding of C₆₀organosols