Publications

2020
Michele Re Fiorentin, Kiptiemoi Korir Kiprono FR. Substitutional impurities in monolayer hexagonal boron nitride as single-photon emitters. Nanomaterials and Nanotechnology. 2020;10:1847980420949349.Abstract

Single-photon emitters in hexagonal boron nitride have attracted great attention over the last few years due to their excellent optoelectronical properties. Despite the vast range of results reported in the literature, studies on substitutional impurities belonging to the 13th and 15th groups have not been reported yet. Here, through theoretical modeling, we provide direct evidence that hexagonal boron nitride can be opportunely modified by introducing impurity atoms such as aluminum or phosphorus that may work as color centers for single-photon emission. By means of density functional theory, we focus on determining the structural stability, induced strain, and charge states of such defects and discuss their electronic properties. Nitrogen substitutions with heteroatoms of group 15 are shown to provide attractive features (e.g. deep defect levels and localized defect states) for single-photon emission. These results may open up new possibilities for employing innovative quantum emitters based on hexagonal boron nitride for emerging applications in nanophotonics and nanoscale sensing devices.

K.K.Korir, Philemon KT. Tailoring single walled carbon nanotube for improved CO2 gas applications: Insights from ab initio simulations. Materialia. 2020;11: 100694.Abstract

Single walled carbon nanotubes has been identified as a potential material for CO2 gas sensing, capture and storage, however, comprehensive understanding of adsorption/desorption mechanisms that drives these application is still lacking yet such knowledge is essential for mainstream application of SWCNT in the identified areas. In this work, we use Density Functional Theory to study CO2 storage and sensing on SWCNTs with the aim of unraveling how such applications can be enhanced with the introduction of dopants with emphasis on Al, B, N and S as potential dopants. It is observed that doping SWCNT with N and B can be easily achieved compared to Al and S, which reported high and positive formation energies thus, can only be achieved under non-equilibrium condition. N doping improves SWCNT interaction with CO2 molecules and when subjected to thermal treatment the adsorbed CO2 is release to the atmosphere at 423 K thus a reusable sensing element can be achieved. It was further observed that the diffusion of molecular CO2 within the proximity of Al and S dopants in SWCNT matrix is not favored, while N and B doped SWCNT tend to have lower barrier energies to CO2, thus can offer better control of carbon storage. Our finding can assist in the design and optimization of SWCNT for energy and environmental applications.

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