The Influence of Zn and Cd Accumulation on the Growth and Development of Medicinal Plants in the Impact Zone of the Novocherkassk Power Station

Over the pastdecade, particular attention has been paid to studies of the chemical composition of medical plants to identify the possible negative consequences of using raw plant material polluted with heavy metals for the production of medical drugs. In our study, we analyzed the chemical composition of the medical plants growing in the impact area of the Novocherkassk power station. Specifically, the plants Artemisia austriaca, Poa pratensis and Elytrigia repenswere examined for the analysis.The content and distribution of Zn and Cd, which are most distributed in industrial emissions and belong to the first class of hazardous elements, were measured. The maximum permissible content (MPC) of Zn in the raw material of Artemisia austriaca and Elytrigia repens was found, as was the maximum content of Cd in all analyzed plants growing in the 5km area around thepower station. The plant Artemisia austriacawasfound to have Zn and Cd accumulation in itsabovegroundcomponents, while in Poa pratensis and Elytrigia repens, accumulation was in the roots. The morphobiometric parameters of the plants were mostly dependent on the soil properties, followed by the degree of technogenic load. The content of Zn and Cd in the medical drugs was higher than the MPC without visible features of heavy metal pollution and so these plants weredangerous for human health. Keywords: heavy metals, technogenic load, phytoreagents, morphometric parameters

Development of ornamental horticulture for residential areas

Aim. Show the ecological significance of ornamental gardening in human life and identify problems of its effective management. Methods. The methods of dialectical cognition of processes and phenomena, monographic empirical and abstract-logical, are used. Results. The issues of the development of domestic ornamental horticulture and floriculture are discussed. A historical overview of landscaping is provided. The researches of domestic and foreign scientists on the toxic effect of pollutants on plant organisms, on the prooxidant-antioxidant balance, and its shift towards the intensification of lipid cross-oxidation in plant tissues, are analyzed. The relevance of research on air transport of harmful substances of human activity in residential areas and the importance of plants in protecting them and residents from the harmful effects of pollutants are shown. Conclusions. Ornamental gardening, floriculture, and landscaping are a promising way to improve the living conditions of the population and neutralize harmful industrial emissions.

Modelling Long-Term Transition from Coal-Reliant to Low-Emission Power Grid and District Heating Systems in Poland

Energy systems require technological changes towards climate neutrality. In Poland, where the power system is dominated by outdated coal-fired power plants, efforts to minimize the environmental impact are associated with high costs. Therefore, optimal paths for the development of the energy sector should be sought in order to achieve ambitious long-term strategic goals, while minimizing the negative impact on the consumers’ home budget. A methodology and a model for the development of the electricity and heat generation structure were developed and implemented in market allocation (MARKAL) modelling framework. Two scenarios were presented, i.e., business as usual (BAU) and withdrawal from coal (WFC) scenarios. The calculations showed a significant role of nuclear energy and offshore wind power in the pursuit of climate neutrality of electricity generation. In the BAU scenario, the model proposes to stay with coal technologies using carbon capture and storage systems. Withdrawal from coal (WFC scenario) makes it necessary to replace them by gas-fired power plants with CO2 sequestration. Solar energy can be used both in electricity and district heating. In order to build on the latter technological option, appropriate energy storage techniques must be developed. Geothermal energy is expected to be the key option for district heat generation in the long-term horizon. The proposed development paths guarantee a significant reduction in greenhouse gases and industrial emissions. However, complete climate neutrality is uncertain, given the current degree and dynamics of technological development.

Comparative assessment of aerosol optical properties over a mega city and an adjacent urban area in India

The present work revolves around the comparative analysis of aerosol optical properties in a mega city, Delhi and in a nearby urban area, Rohtak. It is pertinent to note that despite of the close proximity and similar meteorological conditions, the two study locations show significant differences in aerosol characteristics. The study is conducted using ground based Sky-radiometer measurements for a period of one year. The mean annual Aerosol Optical Depth (AOD) at 500 nm over Delhi and Rohtak is observed to be 1.01 and 0.73 respectively, with correlation coefficient of 0.67 and mean absolute difference of 0.51. The magnitude of AOD in Delhi is higher than in Rohtak throughout the year, except in post-monsoon season. The difference in Angstrom exponent (alpha) between the stations is minimal. However, lower magnitude of alpha is observed in Rohtak, indicating presence of more concentration of coarse-mode particles. Single Scattering Albedo (SSA) also shows seasonal variation with significantly lower values in Delhi throughout the year, indicating contribution of absorbing type of aerosols (like black carbon). The volume concentration in fine-size is found to be higher in Delhi than in Rohtak, indicating combined effect of dust, vehicular, biomass burning and industrial emissions. The aerosol classification via relationship between AOD and alpha shows that urban/biomass burning (U/B) aerosols are dominant in Delhi and mixed type (MT) aerosols in Rohtak during winter and pre-monsoon.

A low-carbon future for the North Sea basin

Human emissions of greenhouse gases have caused a predictable rise of 1.2°C in global temperatures. Over the last 70 years, the rise has occurred at a geologically unprecedented speed and scale. To avoid a worsening situation, most developed nations are turning to renewable sources of power to meet their climate commitments, including UK, Norway, Denmark and The Netherlands. The North Sea basin offers many advantages in the transition from fossil fuels by virtue of its natural resources, physical setting, offshore infrastructure and skilled workforce. Nonetheless, the magnitude of the up-front costs and the areas required to achieve net zero emissions are rarely acknowledged. In addition, some of the technologies being planned are commercially immature. In particular, the current cost of capture, transport and disposal of carbon dioxide is problematic, if it is to be applied as a large-scale solution to industrial emissions. To repurpose the North Sea to meet a low-carbon future will require substantial collaboration between governments and industrial sectors. There are nonetheless significant opportunities for companies prepared to switch from the traditional oil and gas business.Supplementary material at https://doi.org/10.6084/m9.figshare.c.5684641

Heavy Metal Pollutants in Snow and Ice from Roosevelt Island, Antarctica

<p>Global industrialization has led to emissions of heavy metal pollutants that are transported to the most remote areas of the planet. Elevated concentrations of heavy metals are ecological toxins in soils, water, and air. Monitoring has only been implemented during the last few decades with anthropogenic emissions superimposed over natural sources. Furthermore, most monitoring programs generally target local sources of emissions near cities rather than large-scale impacts. Thus quantifying safe limits and controlling industrial emissions is complicated by a lack of knowledge about natural sources and variability on regional, hemispheric, and global scales. New baseline studies are needed to determine i) natural background concentrations of heavy metals, ii) contributions of anthropogenic emissions, and iii) the degree to which atmospheric transport affects background heavy metal concentrations. Due to the remoteness of Antarctica, ice cores can be used as sensitive recorders of background heavy metal atmospheric concentrations over thousands of years. This provides the opportunity to determine natural variability and contributions to the atmosphere on a hemispheric scale, as well as dating the onset of anthropogenic emissions. This thesis presents a 2,300-year time-series record of six heavy metals from a new high-resolution coastal ice core from the Ross Sea region of Antarctica. Roosevelt Island is an ice dome located in the north-eastern Ross Ice Shelf, and a 763m deep ice core was collected over two field seasons as part of the Roosevelt Island Climate Evolution (RICE) project. In addition to 31 other trace elements, concentrations of iron, aluminium, manganese, lead, arsenic, and thallium were measured using inductively coupled plasma mass spectrometry (ICPMS) in the RICE ice core, snow pit, and snow precipitation samples. Sample resolution over the 20th century is extremely high (~1.6 months per sample), with ~four-year resolution extending the record back to 2,300 years ago. We use this record to first determine the representativeness of the RICE ice core to Southern Hemisphere atmospheric concentrations of heavy metals, and find that concentrations in snow precipitation are strongly linked to meridional air mass pathways from the South Pacific. Local deposition characteristics and heavy metal seasonality are also examined in the surface snow. The natural sources and variability of the six heavy metals are explored through the last ~2,000 years, and this provides the context for examining changes over the 20th century. We find that iron, aluminium, and manganese are strongly associated with crustal dust and do not exhibit source changes over the 20th century, though significant increases in concentration may be due to anthropogenically induced increases in atmospheric dust. Even when increased variability due to recent increased efficiency of atmospheric transport is taken into account, the change in source emission strength dominates the concentration increases in these elements recorded in the RICE ice core. Thallium concentrations do not increase over the 20th century, and are likely linked to local volcanism. Both lead and arsenic concentrations increase significantly over the 20th century, with the pattern in lead concentrations closely matching existing Antarctic records. These increases are linked to anthropogenic emissions, with peaks during the 1970s and 1980s up to 400% higher than pre-industrial concentrations – well outside the natural variability. However, the ice core record shows a decreasing trend in concentrations of these elements from the mid-1990s to the present. Arsenic concentrations return to within pre-industrial variability, and the timing of this trend coincides with increasing efforts of policy makers in Southern Hemisphere countries to regulate industrial emissions and to promote public awareness of heavy metal pollutants.</p>

Metagenomic Analysis of Microbial Community Structure And Function In A Improved Biofilter With Odorous Gases

Biofilters have been broadly applied to degrade the odorous gases from industrial emissions. A industrial scale biofilter was set up to treat the odorous gases. To explore biofilter potentials, the microbial community structure and function must be well defined. Using of improved biofilter, the differences in microbial community structures and functions in biofilters before and after treatment were investigated by metagenomic analysis. Odorous gases have the potential to alter the microbial community structure in the sludge of biofilter. A total of 90,016 genes assigned into various functional metabolic pathways were identified. In the improved biofilter, the dominant phyla were Proteobacteria, Planctomycetes, and Chloroflexi, and the dominant genera were Thioalkalivibrio, Thauera, and Pseudomonas. Several xenobiotic biodegradation-related pathways showed significant changes during the treatment process. Compared with the original biofilter, Thermotogae and Crenarchaeota phyla were significantly enriched in the improved biofilter, suggesting their important role in nitrogen-fixing. Furthermore, several nitrogen metabolic pathway-related genes, such as nirA and nifA, and sulfur metabolic pathway-related genes, such as fccB and phsA, were considered to be efficient genes that were involved in removing odorous gases. Our findings can be used for improving the efficiency of biofilter and helping the industrial enterprises to reduce the emission of waste gases.

Heavy Metal Pollutants in Snow and Ice from Roosevelt Island, Antarctica

<p>Global industrialization has led to emissions of heavy metal pollutants that are transported to the most remote areas of the planet. Elevated concentrations of heavy metals are ecological toxins in soils, water, and air. Monitoring has only been implemented during the last few decades with anthropogenic emissions superimposed over natural sources. Furthermore, most monitoring programs generally target local sources of emissions near cities rather than large-scale impacts. Thus quantifying safe limits and controlling industrial emissions is complicated by a lack of knowledge about natural sources and variability on regional, hemispheric, and global scales. New baseline studies are needed to determine i) natural background concentrations of heavy metals, ii) contributions of anthropogenic emissions, and iii) the degree to which atmospheric transport affects background heavy metal concentrations. Due to the remoteness of Antarctica, ice cores can be used as sensitive recorders of background heavy metal atmospheric concentrations over thousands of years. This provides the opportunity to determine natural variability and contributions to the atmosphere on a hemispheric scale, as well as dating the onset of anthropogenic emissions. This thesis presents a 2,300-year time-series record of six heavy metals from a new high-resolution coastal ice core from the Ross Sea region of Antarctica. Roosevelt Island is an ice dome located in the north-eastern Ross Ice Shelf, and a 763m deep ice core was collected over two field seasons as part of the Roosevelt Island Climate Evolution (RICE) project. In addition to 31 other trace elements, concentrations of iron, aluminium, manganese, lead, arsenic, and thallium were measured using inductively coupled plasma mass spectrometry (ICPMS) in the RICE ice core, snow pit, and snow precipitation samples. Sample resolution over the 20th century is extremely high (~1.6 months per sample), with ~four-year resolution extending the record back to 2,300 years ago. We use this record to first determine the representativeness of the RICE ice core to Southern Hemisphere atmospheric concentrations of heavy metals, and find that concentrations in snow precipitation are strongly linked to meridional air mass pathways from the South Pacific. Local deposition characteristics and heavy metal seasonality are also examined in the surface snow. The natural sources and variability of the six heavy metals are explored through the last ~2,000 years, and this provides the context for examining changes over the 20th century. We find that iron, aluminium, and manganese are strongly associated with crustal dust and do not exhibit source changes over the 20th century, though significant increases in concentration may be due to anthropogenically induced increases in atmospheric dust. Even when increased variability due to recent increased efficiency of atmospheric transport is taken into account, the change in source emission strength dominates the concentration increases in these elements recorded in the RICE ice core. Thallium concentrations do not increase over the 20th century, and are likely linked to local volcanism. Both lead and arsenic concentrations increase significantly over the 20th century, with the pattern in lead concentrations closely matching existing Antarctic records. These increases are linked to anthropogenic emissions, with peaks during the 1970s and 1980s up to 400% higher than pre-industrial concentrations – well outside the natural variability. However, the ice core record shows a decreasing trend in concentrations of these elements from the mid-1990s to the present. Arsenic concentrations return to within pre-industrial variability, and the timing of this trend coincides with increasing efforts of policy makers in Southern Hemisphere countries to regulate industrial emissions and to promote public awareness of heavy metal pollutants.</p>