Synthesis and characterization of difluoromethylene-homo[60]fullerene, C60(CF2)

Adsorption of molecular hydrogen (H2) on a fullerene (C60) surface: insights from density functional theory and molecular dynamics simulation

Understanding the adsorption behavior of molecular hydrogen (H2) on solid surfaces is essential for a variety of technological applications, including hydrogen storage and catalysis. We examined the adsorption of H2 (∼2800 configurations) molecules on the surface of fullerene (C60) using a combined approach of density functional theory (DFT) and molecular dynamics (MD) simulations with an improved Lennard-Jones (ILJ) potential force field. First, we determined the adsorption energies and geometries of H2 on the C60 surface using DFT calculations. Calculations of the electronic structure help elucidate underlying mechanisms administrating the adsorption process by revealing how H2 molecules interact with the C60 surface. In addition, molecular dynamics simulations were performed to examine the dynamic behavior of H2 molecules on the C60 surface. We accurately depicted the intermolecular interactions between H2 and C60, as well as the collective behavior of adsorbed H2 molecules, using an ILJ potential force field. Our findings indicate that H2 molecules exhibit robust physisorption on the C60 surface, forming stable adsorption structures with favorable adsorption energies. Calculated adsorption energies and binding sites are useful for designing efficient hydrogen storage materials and comprehending the nature of hydrogen's interactions with carbon-based nanostructures. This research provides a comprehensive understanding of H2 adsorption on the C60 surface by combining the theoretical framework of DFT calculations with the dynamical perspective of MD simulations. The outcomes of the present research provide new insights into the fields of hydrogen storage and carbon-based nanomaterials, facilitating the development of efficient hydrogen storage systems and advancing the use of molecular hydrogen in a variety of applications.

Difluoromethylenation of fullerene C70 provides isomeric diversity and availability of equatorial [5,6]-homofullerene C70(CF2)

We report synthesis, isolation, and spectroscopic characterization of the novel [5,6]-open C70(CF2) isomer III along with the already known [6,6]-closed and [6,6]-open C70(CF2) isomers I and II. The compounds were...

Regioselective CF2 functionalization of Sc3N@D3h(5)-C78

We report the first synthesis and computational study of Sc₃N@C₇₈(CF₂) - an analog of the previously reported Sc₃N@C₈₀(CF₂) with a less common carbon cage whose chemical properties presently remain far less studied. Sc₃N@C₇₈ appears to be considerably more reactive toward CF₂ addition than Sc₃N@C₈₀ and somewhat more reactive than C₆₀. Even though the less symmetric D_3h(5)-C₇₈ carbon cage offers far broader opportunities for isomerism than I_h-C₈₀, CF₂ addition to Sc₃N@C₇₈ proceeds regioselectively, similarly to other common fullerene reactions. A DFT survey of the thermodynamic and kinetic aspects of CF₂ addition demonstrates that the regioselectivity is controlled kinetically.

Addition of CF2 group to endohedral fullerene Sc3N@Ih-C80

We report the first successful synthesis of a CF₂ derivative of the stable endohedral fullerene Sc₃N@I_h-C₈₀. Reaction with CF₂ClCOONa yields a single C_s-symmetric Sc₃N@C₈₀(CF₂) adduct where the CF₂ group is inserted into a [6,6]-bond and opens it to 2.3 Å between the bridgehead carbon atoms. As evidenced by absorption and fluorescence spectroscopy as well as cyclic voltammetry, both the HOMO and the LUMO level of Sc₃N@C₈₀(CF₂) are slightly (ca. 0.1 eV) downshifted with respect to the parent Sc₃N@I_h-C₈₀, so the HOMO-LUMO gap remains essentially unchanged. The DFT calculations suggest that the reaction mechanism is not the previously assumed [2 + 1]-cycloaddition of :CF₂ carbene but rather nucleophilic addition of CF₂Cl^- anion followed by elimination of Cl^- and closing of the CF₂ bridge via intramolecular nucleophilic substitution. Selective formation of the [6,6]-Sc₃N@C₈₀(CF₂) turns out to be kinetically controlled and promoted by a particular orientation of the endohedral Sc₃N cluster with respect to the CF₂Cl^- addition site. In its turn, the CF₂ addend partly hampers the rotation of Sc₃N the endohedral cluster compared to its quasi-free reorientations in the parent Sc₃N@I_h-C₈₀.

Synthesis of homoazafullerene [C59N(CH2)]R and azahomoazafullerene [C59N(NH)]R

The selective insertion of a CH₂ or NH group is achieved through the PCl₅ induced reaction of a CH₂OH or NHOH group, respectively.

[6,6]-Open and [6,6]-closed isomers of C70(CF2): synthesis, electrochemical and quantum chemical investigation

Novel difluoromethylenated [70]fullerene derivatives, C70(CF2 )n (n=1-3), were obtained by the reaction of C70 with sodium difluorochloroacetate. Two major products, isomeric C70(CF2 ) mono-adducts with [6,6]-open and [6,6]-closed configurations, were isolated and their homofullerene and methanofullerene structures were reliably determined by a variety of methods that included X-ray analysis and high-level spectroscopic techniques. The [6,6]-open isomer of C70(CF2 ) constitutes the first homofullerene example of a non-hetero [70]fullerene derivative in which functionalisation involves the most reactive bond in the polar region of the cage. Voltammetric estimation of the electron affinity of the C70(CF2 ) isomers showed that it is substantially higher for the [6,6]-open isomer (the 70-electron π-conjugated system is retained) than the [6,6]-closed form, the latter being similar to the electron affinity of pristine C70. In situ ESR spectroelectrochemical investigation of the C70(CF2 ) radical anions and DFT calculations of the hyperfine coupling constants provide evidence for the first example of an inter-conversion between the [6,6]-closed and [6,6]-open forms of a cage-modified fullerene driven by an electrochemical one-electron transfer. Thus, [6,6]-closed C70(CF2 ) constitutes an interesting example of a redox-switchable fullerene derivative.

SEARCHING FOR NEW MEMBERS OF C70 HOMOFULLERENES BY FIRST-PRINCIPLES COMPUTATIONS: BENT'S RULE AT WORK ON C70 SURFACE

We carried out systematic density functional theory computations to search for new members of C70 homofullerenes inspired by the Bent's rule. By substituting CH2 by CF2 , we identified five experimentally accessible C70 homofullerenes, among which one member has different bonding character as its CH2 counterpart (where the closed three-membered ring is formed by CH2 addition). This unique C70 homofullerene is expected to be synthesized very smoothly using the standard solution phase chemistry, due to its high thermodynamic stability and the rather high local reactivity of the carbon bond attached to the CF2 addend.

Smooth and jump-like metal-dielectric transitions in single-walled carbon nanotubes under functionalization

We examine at the DFT level of theory the topology of side wall functionalization of the (5,5)metallic single-wall carbon nanotube (CNT) with carbenes (>CX(2)) and its effect on electronic properties of the system. It is demonstrated that specific substructures/topology known to stabilize functionalized fullerene molecules can play the same role in CNTs, as well. Upon deepening of functionalization, "uniformity" of addition motives and related continuous changes in properties transform into regular addition patterns with isolated aromatic islands on the nanotube backbone that give rise to jump-like changes in electronic structure.

Novel possibilities in the study of isolated carbon nanotubes

We report the first detection of carbon nanotubes in the gas phase in a matrix-assisted laser desorption/ionization (MALDI) mass spectrometric experiment. These observations open the possibility of studying isolated nanotubes in the gas phase by means of various spectroscopic methods and a possible way to separate them.