Thorium extraction techniques, such as solvent extraction from monazite and electrosorption techniques from water leach purification (WLP) of radioactive waste residues, are important for thorium recovery, particularly in Malaysia. Despite their importance, previous studies have largely overlooked critical issues like radioactive hazards, human health risks, and environmental impacts associated with advanced thorium extraction methods. This study addresses these gaps by quantifying the environmental impact associated with solvent extraction and electrosorption techniques using a life cycle assessment (LCA) framework to compare environmental indicators for thorium recovery from monazite ore and WLP residues. The LCA was conducted from cradle to gate, incorporating inventory data from the Ecoinvent database 3 and SimaPro software version 9, with inputs of raw material extraction, transportation, energy consumption, and chemical uses. Emissions into air, water, and soil were quantified across all processing phases. The LCA midpoint findings reveal that thorium disulfate in monazite processing is the key contributor to global warming, producing 45 kg CO2-eq, whereas transportation and electricity consumption also considerably affect emissions, contributing 25.07 kg CO2-eq and 26.17 kg CO2-eq, respectively. Comparative analysis of midpoint indicators showed that solvent extraction had a more significant environmental impact than electrosorption in the context of human carcinogenic toxicity, freshwater ecotoxicity, and marine ecotoxicity. The damaged assessment highlighted endpoint indicators that monazite processing had a higher impact than WLP on human health (0.0364-0.0016 DALY), ecosystems (0.0016-0.0005 species & sdot;yr), and resources (0.0012-0.0005 USD, 2013), primarily due to the use of chemicals and emissions. Our study shows that electrosorption from WLP demonstrates superior environmental sustainability compared with solvent extraction from monazite, positioning it a more viable and efficient approach for radioactive waste treatment.

The Peles Park Forest (PPF), a semi-natural peri-urban forest near Sinaia, Romania, is essential in providing ecological benefits and improving human well-being through recreation. As the urban population grows and stress-related health problems increase, green spaces are increasingly recognised for their restorative functions, including air purification, temperature regulation and mental health improvement. This study aims to develop a sustainable management framework that reconciles forest conservation with recreational value use by assessing forest structure, evaluating tourism-related stressors, and proposing adaptive management strategies. We assessed forest structure through tree diameter, height, volume, and crown health measurements, applying principal component analysis (PCA) to identify the main structural drivers. The results revealed a strong correlation between tree diameter and height, modulated by species composition and site conditions. They showed pronounced crown defoliation in the upper canopy layers, particularly among trees of lower wood quality. The findings suggest that uneven-aged stand structures, which support biodiversity and ecological resilience, are subject to tourism-related pressures such as soil compaction and vegetation damage.

introduction: The study investigates the impact of atmospheric fluoride emitted from brick kilns on soil fertility and earthworm activity in fruit orchards in South Asia. Due to the proximity to unregulated kilns, local fruit productions like peaches and plums have seen a decline. The brick kiln emissions, primarily fluoride in the form of hydrogen fluoride (HF), have been shown to negatively affect both plant life and soil health, particularly impacting earthworms which are crucial for soil nutrient cycling. Method: The research focused on peach and plum orchards near Peshawar, within 500 meters of brick kilns. Soil and leaf samples were collected and analyzed for fluoride content. Earthworm experiments were conducted to assess the impact of fluoride on their growth and reproduction by exposing them to contaminated leaf litters. Results: The results showed elevated levels of fluoride in both soil and leaf samples from the proximity of brick kilns. Earthworms exposed to this contaminated environment exhibited reduced growth rates and cocoon production, highlighting the detrimental effects of fluoride on soil biota. This aligns with previous findings that link industrial emissions to ecological damage in agricultural settings. Conclusion and Recommendations: The study confirms that fluoride emissions from brick kilns can substantially decrease soil fertility and harm earthworm populations, which are vital for maintaining soil health. It recommends implementing strategies such as using calcium-rich amendments, enhancing organic matter in the soil, and regular monitoring of soil fluoride levels to mitigate these effects. These measures could improve soil conditions, thereby supporting healthier crop growth and restoring ecological balance in affected areas.

Soil-borne plant diseases significantly threaten agricultural sustainability, leading to substantial crop loss. Although chemical pesticides are effective, their environmental and health risks are concerning. Recently, compost has gained attention as a sustainable alternative for managing plant pathogens. Its effectiveness is due to its physical (e.g., particle aggregation and moisture retention), chemical (e.g., pH, electrical conductivity, nutrient balance, and humic substances), and biological properties (e.g., diverse microbial communities). These properties contribute to pathogen suppression through direct mechanisms, involving the release of toxic compounds and competition with compost-introduced microbiota, and indirect mechanisms, including the modulation of plant biochemical pathways, alleviation of oxidative damage, enhancement of defense-related enzymatic activities, and induction of systemic resistance. Overall, this review groups and classify the mechanisms induced by compost, highlighting its potential as a natural substitute to chemical pesticides.

This paper provides characteristic and a comprehensive overview of the adaptation strategies of sessile oak (Quercus petraea [Matt.] Liebl.) in the context of global climate change (GCC). The GCC is primarily manifested by increasing air temperatures and changing precipitation distribution. It poses a significant challenge to tree species including sessile oak, affecting its capacity for adaptation and survival. Despite the challenge, sessile oak shows significant drought tolerance due to its deep-reaching root system, which allows the tree to use available water more efficiently. Other adaptive strategies include the establishment of mixed stands that increase the resilience and biodiversity of the ecosystem. Adjustments of stand density through tending interventions play a significant role, helping to improve the stress resistance of stands. Additionally, coppice forest cultivation is applied on extremely dry sites. The sessile oak is also significant for its ecological plasticity - its ability to thrive on versatile soil and climatic conditions makes it a promising tree species for future forest management. Mixed stands with sessile oak and other tree species can enhance the ecosystem services of forests and also increase their endurance to GCC events. However, sessile oak faces several challenges, including the increasing risk of damage from pests and pathogens that require targeted measures for its protection and sustainable cultivation. The literature review suggests that a comprehensive understanding of sessile oak's ecological requirements and interactions with the environment is crucial for its successful adaptation to GCC and the formulation of effective strategies for its protection and use in forest management.

Research on mountain ecosystem services (MES) under the influence of climate change and human activities has gradually become the focus of academic attention in recent years. Here, this study analyzes the research hotspots and frontiers of this field based on metrics including main research forces, core journals and papers, research hotspots and topics by using the methods of bibliometrics and text mining. The results revealed the following: (1) the number of papers is increasing rapidly in recent years. From 2015 to 2019, 929 papers were published, with an average of 185 papers per year. But the average cited times of those papers is declining, dropped from 6.01 in 2016 to 4.2 in 2019. The USA, UK, and China rank the top three of the number of papers. Univ Maryland, Univ Oxford and Univ Wisconsin have the greatest influence, with an average of more than 77 citations per paper; (2) The most cited journals are PNAS, WETLANDS, ECOLOGY, AND SOCIETY, which are cited 191.54, 53.91, and 40.00 respectively. Most papers were published in OA journals including SUSTAINABILITY, WATER, Forests since 2017. Ten core papers undertaking knowledge transfer in this field have been identified; (3) analysis of the keywords found a new trend of integration of natural science and humanities. In two development stages of 2000-2014 and 2015-2019, the research hotspots mainly focused on mountain water resources, forest resources, land resources and the impact of climate change and human activities, and there are obvious differences and characteristics in different stages. The hotspot worthy of attention in the near future is the assessment of mountain ecosystem services capacity and value. This is the first comprehensive visualization and analysis of the research hotspots and trends of mountain ecosystem services.