Current Environmental Engineering最新文献

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The contribution of biogas to the fertility of Bengali soils 沼气对孟加拉土壤肥力的贡献

Current Environmental Engineering

Pub Date : 2018-10-03 DOI: 10.2174/2212717805666181003141827

W. J. Oosterkamp

引用次数: 0

Meet Our Editorial Board Member 见见我们的编辑委员会成员

Current Environmental Engineering

Pub Date : 2018-07-20 DOI: 10.2174/221271780502180718165608

Jingdong Zhang

引用次数: 0

Nano Zero Valent Iron Composites for Water Decontamination: A Review 纳米零价铁复合材料用于水净化研究进展

Current Environmental Engineering

Pub Date : 2018-07-20 DOI: 10.2174/2212717805666180405123523

Nivedita Shukla, A. Saxena, Vatsana Gupta, A. S. Rawat, Sarita Shrivastava, P. Rai

引用次数: 3

Assessing Impact of Land-use Change on the Hydrological Response for Mellegue River, Tunisia 土地利用变化对突尼斯Mellegue河水文响应的影响评估

Current Environmental Engineering

Pub Date : 2018-07-20 DOI: 10.2174/2212717805666180511113914

Nabil Khorchani, Khaldoon A Mourad, L. Ribbe

引用次数: 2

Elemental Fingerprint of Agriculture Soils of Eastern Region of the Arabian Desert by ICP-OES with GIS Mapping 基于ICP-OES和GIS制图的阿拉伯沙漠东部地区农业土壤元素指纹图谱

Current Environmental Engineering

Pub Date : 2018-07-20 DOI: 10.2174/2212717805666180507155251

R. Ajaj, Suzan Shahin, S. Kurup, A. Cheruth, M. Salem

引用次数: 6

Reducing the environmental impact of manures from dairy farms 减少奶牛场粪便对环境的影响

Current Environmental Engineering

Pub Date : 2018-06-07 DOI: 10.2174/2212717805666180607093150

W. J. Oosterkamp

引用次数: 0

Magnetic Halloysite/Fe3O4/AuNPs Nanocomposite as a Recyclable Efficient Catalyst for Hydrogenation of Congo Red and 4-Nitrophenol 磁性高岭土/Fe3O4/AuNPs纳米复合材料作为刚果红和4-硝基苯酚加氢的可回收高效催化剂

Current Environmental Engineering

Pub Date : 2017-11-03 DOI: 10.2174/2212717804666171103110721

Aiqin Wang, Yuru Kang, Wenbo Wang, Dong Wenkai

引用次数: 2

Adsorption of Reactive Blue 19 Dye by Sugarcane Bagasse and the Proposed Modelling 甘蔗渣对活性蓝19染料的吸附及模拟

Current Environmental Engineering

Pub Date : 1969-12-31 DOI: 10.2174/2212717804666171013153134

D. S. Kharat

引用次数: 1

Evaluating the Implications of Climate Projections on Heat Hardiness Zones for Green Infrastructure Planning 评估气候预估对绿色基础设施规划耐热区的影响

Current Environmental Engineering

Pub Date : 1969-12-31 DOI: 10.2174/2212717806666190204102225

L. Sylvester, O. Omitaomu, Esther S. Parish, B. Bhaduri

Background: Green Infrastructure (GI) is widely being promoted as an adaptationstrategy for urban flooding. Like urban flooding, tree species could be impacted by futureclimatic conditions. However, there have been limited studies on the implications of futureclimate on GI planning, mostly due to the lack of climate data at higher spatial resolutions. In this paper, we analyze the implications of climate projections on heat hardinesszones since this could impact the GI landscape in the coming years. This is an extension ofour earlier work on evaluating impacts of climate projections on plant hardiness zones.Method: Using downscaled daily temperature data from ten Coupled Model IntercomparisonProject Phase 5 (CMIP5) climate models for the historical (1980 - 2005) and projected (2025- 2050) periods, we analyzed future heat hardiness zones in the watershed bounding KnoxCounty, TN. We analyzed the implications of these outputs for the current list of suggestednative and non-native tree species selected for GI in the study area. All the models suggest that a considerable part of the study area will move into thenext warmer heat zone. While most trees remain suitable for GI, several are at the limit oftheir ideal heat zones. The insights from this study will help guide the selection and placement of GIacross the study area. Specifically, it should help green infrastructure planners design bettermitigation and adaptation strategies to achieve higher returns on investments as more citiesare now investing in GI projects.

背景:绿色基础设施(GI)作为一种适应城市洪水的策略被广泛推广。就像城市洪水一样，树种也会受到未来气候条件的影响。然而，由于缺乏更高空间分辨率的气候数据，对未来气候对地理标志规划的影响研究有限。在本文中，我们分析了气候预估对热硬性区的影响，因为这可能会影响未来几年的地理标志景观。这是我们早期关于评估气候预测对植物抗寒区影响的工作的延伸。方法:利用10个耦合模式比较项目第5阶段(CMIP5)气候模式在历史(1980 - 2005)和预测(2025- 2050)时期的缩小比例的日温度数据，分析了田纳西州诺克斯县流域未来的耐热区，并分析了这些输出结果对研究区域当前推荐的用于地理特征选择的本地和非本地树种的影响。所有的模型都表明，研究区域的相当一部分将进入下一个更温暖的热区。虽然大多数树木仍然适合GI，但有几种树木已经达到了理想热区的极限。本研究的见解将有助于指导gii在整个研究区域的选择和安置。具体来说，它应该帮助绿色基础设施规划者设计更好的缓解和适应战略，以实现更高的投资回报，因为现在越来越多的城市投资于地理标志项目。

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引用次数: 2

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