Ultradoping Boron on Si(100) via Solvothermal Chemistry*.

Ultradoping introduces unprecedented dopant levels into Si, which transforms its electronic behavior and enables its use as a next-generation electronic material. Commercialization of ultradoping is currently limited by gas-phase ultra-high vacuum requirements. Solvothermal chemistry is amenable to scale-up. However, an integral part of ultradoping is a direct chemical bond between dopants and Si, and solvothermal dopant-Si surface reactions are not well-developed. This work provides the first quantified demonstration of achieving ultradoping concentrations of boron (∼1e14 cm2 ) by using a solvothermal process. Surface characterizations indicate the catalyst cross-reacted, which led to multiple surface products and caused ambiguity in experimental confirmation of direct surface attachment. Density functional theory computations elucidate that the reaction results in direct B-Si surface bonds. This proof-of-principle work lays groundwork for emerging solvothermal ultradoping processes.

Drosophila bioassays are very sensitive methods to assess tarantula species venoms.

INTRODUCTION: Assaying venom toxicity in a suitable model system is often tricky, since normally the amount of venom is in short supply, and the assay subjects, i.e., typically mice, require large amounts. There is also no guarantee that the effects observed in the bioassay reflect the true nature of the venom's intended effects, as the animals used for assessment might not be the prey items to which the venom has evolved. METHODS: We harvested tarantula venoms from the Indian Poecilotheria regalis and the Mexican Bonnetina papalutlensis using light anesthesia and electrical stimulation. We follow the definition of venom as stated in (Nelsen et al., 2014). The recovered venom was lyophilized and reconstituted in sterile saline solution for injections. Drosophila melanogaster third instar larvae and adult flies were injected with 4.6 nanoliters of different concentrations of the venoms into the sixth abdominal segment, and scored for survival and development to adulthood. RESULTS: The injected venoms were very effective in provoking lethality of injected larvae and adults, with an LD50 of 1-5 nanomoles protein /gram wet weight. Comparison with other toxicity bioassays, i.e., mice and crickets -using the same P. regalis venom- renders the Drosophila bioassays three orders of magnitude more sensitive. The P. regalis and B. papalutlensis venoms have similar LD50. DISCUSSION: These bioassays use a small amount of venom compared to other bioassays, allowing characterization with far fewer starting material. As it uses insects, phylogenetically close to the intended prey victims, it also points to the efficiency of the tarantula venom for its preferred prey items, and thus, links as well to the tarantulas' ecology.

HfSe2 thin films: 2D transition metal dichalcogenides grown by molecular beam epitaxy.

In this work, we demonstrate the growth of HfSe2 thin films using molecular beam epitaxy. The relaxed growth criteria have allowed us to demonstrate layered, crystalline growth without misfit dislocations on other 2D substrates such as highly ordered pyrolytic graphite and MoS2. The HfSe2 thin films exhibit an atomically sharp interface with the substrates used, followed by flat, 2D layers with octahedral (1T) coordination. The resulting HfSe2 is slightly n-type with an indirect band gap of ∼ 1.1 eV and a measured energy band alignment significantly different from recent DFT calculations. These results demonstrate the feasibility and significant potential of fabricating 2D material based heterostructures with tunable band alignments for a variety of nanoelectronic and optoelectronic applications.