Observations of MeV electrons in Jupiter's innermost radiation belts and polar regions by the Juno radiation monitoring investigation: Perijoves 1 and 3

Juno's "Perijove 1" (27 August 2016) and "Perijove 3" (11 December 2016) flybys through the innermost region of Jupiter's magnetosphere (radial distances J at closest approach) provided the first in situ look at this region's radiation environment. Juno's Radiation Monitoring Investigation collected particle counts and noise signatures from penetrating high-energy particle impacts in images acquired by the Stellar Reference Unit and Advanced Stellar Compass star trackers, and the Jupiter Infrared Auroral Mapper infrared imager. This coordinated observation campaign sampled radiation at the inner edges of the high-latitude lobes of the synchrotron emission region and more distant environments. Inferred omnidirectional >5 MeV and >10 MeV electron fluxes derived from these measurements provide valuable constraints for models of relativistic electron environments in the inner radiation belts. Several intense bursts of high-energy particle counts were also observed by the Advanced Stellar Compass in polar regions outside the radiation belts

Use of natural sorbents for accelerated bioremediation of grey forest soil contaminated with crude oil

13 páignas.- 7 figuras.- 2 tablas.- referencias.- Supplementary data to this article can be found online at https://doi.org/10.1016/j.scitotenv.2022.157952.Due to the extensive oil extraction and transportation that occurs in oil-producing countries, many lands remain contam-inated because of accidental leakages. Despite its low cost and environmentally safe nature, bioremediation technology is not always successful, mainly because of the soil toxicity to the degrading microbial populations and plants. Here we re-port a three-year microfield experiment on the influence of natural sorbents of mineral (zeolite, kaolinite, vermiculite, di-atomite), organic (peat), carbonaceous (biochar) origin, and a mixed sorbent ACD (composed of granular activated carbon and diatomite) on the bioremediation of grey forest soil contaminated with weathered crude oil (40.1 g total petroleum hydrocarbons (TPH) kg-1). Optimal doses of the sorbents significantly accelerated bioremediation of petroleum -contaminated soil through bioaugmentation followed by phytoremediation. The main reason for the influence of the sor-bent amendments relied upon the creation of optimal conditions for the activation of hydrocarbon-utilizing bacteria and plant growth due to the reduction of soil toxicity, as well as maintaining an optimal pH and water-air regime in the soil. That happened because of reducing the soil hydrophobicity, increasing porosity and water holding capacity. The content of the TPH in the best samples (2 % biochar or ACD) reduced to their local permissible concentration accepted for remediated soils in the Russian Federation (<= 5 g kg-1) after two warm seasons compared to that after three warm sea-sons in the other samples. Although some sorbents decelerated biodegradation of highly condensed polycyclic aromatic hydrocarbons (PAHs, including benzo(a)pyrene) in the soil, the overall risk from the residual contaminants present in the remediated soil and plants was minimized. The final total content of the main PAHs in the sorbent-amended soils did not exceed the maximal permissible levels that are accepted in most EU countries (1000-40,000 mu g kg-1), and they did not accumulate in the aboveground phytomass of grasses in dangerous concentrationsThis work was fi nanced by the Russian Science Foundation (Project No. 19-29-05265mk) . We thank the Spanish Ministry of Science, Innovation (PID2019-109700RB-C1) for supporting the work of J.J. Ortega-Calvo, as well as Dr. Christina Ivashchenko for consultation in statistical treatment of our results.Peer reviewe