Abstract
We have employed fullerenes as versatile agents to “cork” the open tips of multiwalled carbon nanotubes (MWCNTs), and as promoting species for the release of the inorganic material filled within the nanotubes’ cavities. High Z element compounds, namely, PbI2, ZnI2, and CeI3, were chosen to easily determine the presence of the filler inside the hosting nanotubes by transmission electron microscopy (TEM). Fullerenes can isolate inorganic nanostructures confined within the hollow cavities of MWCNTs, which allows the removal of the external material remnant after the filling. Otherwise, taking advantage of the affinity of fullerenes with selected solvents, we have confirmed the ability of the C60 molecules to promote the displacement of the inorganic guest from the host. We propose two different strategies to trigger the release, employing vapor and liquid phase treatments. The first protocol involves annealing filled MWCNTs in presence of fullerenes (to obtain C60PbI2@MWCNTs) and the subsequent washing of the sample in ethanol under mild conditions. On the other hand, the simultaneous introduction of the C60 molecules and the liberation of the guest are produced by a single step wet procedure; the latter being potentially useful when materials that are not stable at high temperatures are employed for filling.
Highlights
The wide range of diameters of both single walled (SWCNTs) and multiwalled carbon nanotubes (MWCNTs) make their cavities susceptible of filling with diverse foreign species
The inorganic material present inside the cavities of MWCNTs is distinguishable from CNTs when these are observed by transmission electron microscopy (TEM), which was employed to verify the encapsulation of PbI2 within the MWCNTs cavities
Since the contrast in TEM imaging is highly dependent on the atomic/molecular weight of the material, PbI2 was chosen as a model compound for filling MWCNTs
Summary
The wide range of diameters of both single walled (SWCNTs) and multiwalled carbon nanotubes (MWCNTs) make their cavities susceptible of filling with diverse foreign species. The presence and nature of the guest material into the hollow cavities can alter the properties of the hosting template, improving its optical and electrical behavior (del Carmen Giménez-López et al, 2011). Hybrid materials with diverse characteristics are obtained These can be used in a myriad of applications, namely, molecular magnets (del Carmen Giménez-López et al, 2011), optoelectronics and photovoltaics (Zhou et al, 2015), battery electrodes (Prem Kumar et al, 2004), catalysis (Pan and Bao, 2008), or biomedicine (Klingeler et al, 2008; Martincic and Tobias, 2015)
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