全文获取类型
收费全文 | 136篇 |
免费 | 47篇 |
国内免费 | 147篇 |
专业分类
安全科学 | 12篇 |
废物处理 | 5篇 |
环保管理 | 7篇 |
综合类 | 253篇 |
基础理论 | 10篇 |
污染及防治 | 8篇 |
评价与监测 | 34篇 |
灾害及防治 | 1篇 |
出版年
2024年 | 5篇 |
2023年 | 20篇 |
2022年 | 26篇 |
2021年 | 41篇 |
2020年 | 41篇 |
2019年 | 25篇 |
2018年 | 19篇 |
2017年 | 14篇 |
2016年 | 10篇 |
2015年 | 14篇 |
2014年 | 17篇 |
2013年 | 17篇 |
2012年 | 16篇 |
2011年 | 14篇 |
2010年 | 6篇 |
2009年 | 6篇 |
2008年 | 6篇 |
2007年 | 3篇 |
2006年 | 2篇 |
2005年 | 2篇 |
2004年 | 4篇 |
2003年 | 8篇 |
2002年 | 2篇 |
2001年 | 1篇 |
2000年 | 1篇 |
1999年 | 3篇 |
1997年 | 3篇 |
1993年 | 1篇 |
1992年 | 2篇 |
1986年 | 1篇 |
排序方式: 共有330条查询结果,搜索用时 93 毫秒
21.
22.
Ionic composition of submicron particles (PM1.0) during the long-lasting haze period in January 2013 in Wuhan, central China 总被引:1,自引:0,他引:1
Hairong Cheng Wei Gong Zuwu Wang Fan Zhang Xinming Wang Xiaopu Lv Jia Liu Xiaoxin Fu Gan Zhang 《环境科学学报(英文版)》2014,26(4):810-817
In January 2013, a long-lasting severe haze episode occurred in Northern and Central China; at its maximum, it covered a land area of approximately 1.4 million km2. In Wuhan, the largest city in Central China, this event was the most severe haze episode in the 21st century. Aerosol samples of submicron particles (PM1.0) were collected during the long-lasting haze episode at an urban site and a suburban site in Wuhan to investigate the ion characteristics of PM1.0 in this area. The mass concentrations of PM1.0 and its water-soluble inorganic ions (WSIIs) were almost at the same levels at two sites, which indicates that PM1.0 pollution occurs on a regional scale in Wuhan. WSIIs (Na+, NH4+, K+, Mg2+, Ca2+, Cl-, NO3- and SO42-) were the dominant chemical species and constituted up to 48.4% and 47.4% of PM1.0 at WD and TH, respectively. The concentrations of PM1.0 and WSIIs on haze days were approximately two times higher than on normal days. The ion balance calculations indicate that the particles were more acidic on haze days than on normal days. The results of the back trajectory analysis imply that the high concentrations of PM1.0 and its water-soluble inorganic ions may be caused by stagnant weather conditions in Wuhan. 相似文献
23.
2013-2015年上海市霾污染事件潜在源区贡献分析 总被引:6,自引:0,他引:6
统计分析2013-2015年上海市每个月不同空气质量等级天数比重,根据HYSPLIT(Hybrid Single Particle Lagrangian Integrated Trajectory)后向轨迹模型对3年内的12月份影响上海地区的污染气团进行了综合聚类分析和逐年聚类分析.在综合12次严重霾事件的后向轨迹基础上,结合上海实时公布的PM2.5小时浓度资料,对潜在源贡献因子PSCF(Potential Source Contribution Function)和浓度权重轨迹CWT(Concentration-weighted Trajectory)进行分析与比较,研究重霾期间影响上海PM2.5质量浓度的潜在源区及不同源区对PM2.5质量浓度的贡献差异.结果显示,上海市3年期间12月份霾颗粒物外来源主要输送渠道为西北路径和北方路径,源自于西北方向的气团比重占总气团的50.4%,北方向的气团几乎都经过海洋后进入上海地区.影响上海地区PM2.5质量浓度的潜在源区主要分布在安徽、江苏和山东地区,此外江西北部、浙江北部、河北南部及山西少部分地区也对重霾事件中的污染物颗粒有一定程度的贡献. 相似文献
24.
Samura Alusine Al-Agha Omar Tuncel Semra G. 《Water, Air, & Soil Pollution: Focus》2003,3(5-6):111-129
The concentrations of heavy, trace elements and major ions measuredin the Uluda and Bursa aerosols were investigated to assess size distributions, spatial and temporal variability, sources and source regions affecting the composition of aerosols in Uluda and Bursa. A total of 81 samples were collected in two sites, one in Bursa city and another in the Uluda Mountain during two sampling campaigns. Daily samples were collected using a high volume sampler on Whatman 41 cellulose filters in Uluda, while three days interval samples were collected in Bursa using an automatic dichotomous sampler on PTFE Teflon filters. Samples were analysed for 15 trace and heavy metals (Al, Fe, Ba, Na, Mg, K, Mn, Ca, Cu), (V, Pb, Cd, Cr, Ni, Zn), and 4 major ions (SO4
2-, NO3
-, Cl-), (NH4
+) using ICP-AES, GFAAS, HPLC and UV/VIS Spectrophotometer,respectively. In general, concentrations of the metals measured inUluda aerosols were lower than those in Bursa. The concentrations of crustal elements were higher in summer than winter, while anthropogenic elements had higher concentrations in winter than summer. Most of the mass of crustal elements was concentrated in the coarse mode while the mass of the heavy metals was concentrated in the fine mode. Factor analysis revealed four factors with sources including crustal, industrial and combustion. Back trajectory calculations were used to determine long range contributions. These calculations showed that contributions were mostly from European countries, former Soviet Union countries, Black Sea and North Africa. 相似文献
25.
Cao Junji Lee Shungcheng Zheng Xiangdong Ho Kinfai Zhang Xiaoye Guo Hai Chow Judith C. Wang Hongbin 《Water, Air, & Soil Pollution: Focus》2003,3(2):213-229
In April 1998, two intense dust storms were generated in CentralAsia and transported eastward across East Asia (15 and 19 April). This article presents the chemical characterization ofHong Kong (HK) aerosols during the dust storms. During the 15 Aprildust storm, hourly respiratory suspended particles (RSP)(particle diameter smaller than 10 m) concentrationsmonitored at 7 sites in Hong Kong reached the peak valuessynchronously between 9 and 11 a.m. on 17 April, in which thehighest concentration was 267 g m-3. Analysis ofthe RSP samples showed that concentrations of crustalelements (Ba, Ca, Cd, Cr, Fe, Mg, K+) and anthropogenicspecies (As, Ni, Pb, Zn, NH4
+, NO3
-,SO4
2- and total carbon) were substantiallyenhanced. Enhancement of these species was more than afactor of 2 to 14 relative to the non dust period. The totalcarbon content was high, at 59 g m-3 (notincluding carbonate), and the enrichment factors of Asand Pb on 17 April were 122 and 117, respectively. Thisimplied that anthropogenic materials together with mineraldust were transported to HK from Mainland China. Based onmaterial balance calculations, mineral dust contributed41% to the observed RSP mass on 17 April, which was 2 times thatof the nondust sample (22%). From the 5-day backwardtrajectory analysis, this storm was transported directlyfrom Northwest China to HK. However, there was nocorresponding observation for the 19 April dust stormaerosol. Consequently, 15 April storm had stronger impact onHK's atmosphere than 19 April storm. Compared to the HK AirQuality Objective, 15 April dust storm did not cause seriousair pollution in HK. 相似文献
26.
利用2018年3月—2021年2月环境和气象数据对皖南地区铜陵市大气颗粒物的污染特征和潜在贡献源进行了系统性研究.铜陵市大气颗粒物污染具有明显的季节变化特征,冬季污染物浓度最高,PM2.5和PM10平均为(60.3±31.0)μg·m-3和(89.2±42.2)μg·m-3.计算发现PM2.5/PM10超过0.5,铜陵市的大气颗粒物污染问题与细颗粒物关系密切.后向轨迹聚类分析表明铜陵市大气颗粒物的输送路径具有季节性差异.春季以西北、东北和西南方向气流为主,占比83.73%;夏季以东南和南部方向气流为主,占比82.90%;秋季以东北气流为主,占比51.00%;冬季则是以北方和西北气流为主,占比69.81%.其中,冬季气流轨迹所对应的PM2.5和PM10的浓度最高,平均为59.7和92.0μg·m-3;夏季最低,平均为23.8和43.8μg·m-3.潜在源贡献因子(WPSC... 相似文献
27.
为了解天津市采暖季PM2.5中重金属的污染特征及健康风险,使用Xact-625重金属在线分析仪于2020年11月至2021年3月对PM2.5中的重金属元素进行连续采样,分析10种重金属元素(Pb、 Cd、 Cr、 As、 Zn、 Mn、 Co、 Ni、 Cu和V)的污染特征,利用HYSPLIT模型分析重金属元素的时空分布特征,并结合美国EPA健康风险评价模型对重金属健康风险展开研究.结果表明,采样期间天津市10种重金属元素的总浓度平均值为(261.56±241.74)ng·m-3,Cr[折算Cr(Ⅵ)]和As元素高于《环境空气质量标准》(GB 3095-2012)的年平均限值.后向轨迹分析表明,天津市主要受到来自西北部中距离气团(1号)、西北部长距离气团(2号)、西南部气团(3号)和东北部气团(4号)的影响.不同气团来向重金属元素呈现不同的污染特征和健康风险,3号气团PM2.5浓度、10种重金属元素总浓度和5种重金属元素经呼吸途径暴露的终身致癌风险值之和均最高,2号气团10种重金属元素经呼吸途径暴露... 相似文献
28.
全国大气扩散输送模态与区划研究 总被引:5,自引:3,他引:2
基于NCEP再分析气象资料,使用HYSPLIT模式对我国大陆区域进行了一整年的连续轨迹计算.轨迹以1°×1°的网格化经纬度分辨率进行计算.考虑气候、地理及经济因素,将全国计算区域分为10个大区,分别统计各大区出发的轨迹在全国的分布频率.根据全年和各季的轨迹统计结果,分析我国不同区域的大气输送扩散特征以及区域间大气环境的相互影响潜势.结果表明,全国10个大区的大气扩散输送模态可分为特性不同的7大类,其中以西北方向的3个大区为一类,西南高原的2个大区为另一类,其它各区自成一类.10个大区大气扩散物质的累积效应差异显著且季节变化特征各异.全国以西南区(XN)东部大气累积效应最强,东北区(DB)累积效应最弱. 相似文献
29.
2008年到2010年对上海市西南部大气中总汞(TGM———Total Gaseous Mercury)的污染水平进行监测,结果表明TGM日均浓度为ND~57.23ng/m(3(7.79±3.29)ng/m)3。TGM呈现出一定的季节性变化特征,浓度最高的是秋季,然后依次是冬季、春季、夏季,平均浓度分别为(9.30±2.48)、(8.32±2.79)、(7.78±2.33)、(2.16±3.29)ng/m3。TGM浓度受东南风向影响最大,其次为西北和东北风向。在置信水平为95%的情况下,TGM浓度与日平均温度呈正相关性,而与日温差、相对湿度、日相对湿度差、风速无显著相关性。但TGM浓度分别与日均O3浓度和NO2浓度均呈显著正相关。利用HYSPLIT_4模型对TGM浓度高值与低值几天的空气气团来源轨迹进行反演,结果发现高低浓度日的气团来源略有差别,总体上看,冬季、春季和秋季受北方气团影响较大,夏季则受我国东部海域影响,具体的局部和长距离输送的贡献需要进一步研究。 相似文献
30.
利用HYSPLIT后向轨迹模式,结合兰州市AQI(空气质量指数)及常规大气污染物质量浓度数据,模拟研究了2017年1月1日-12月31日以兰州市为受点的大气污染物输送特征.通过聚类分析确定了抵达兰州市气团的主要输送途径和每类路径所对应的污染物质量浓度特征,并利用受体模型PSCF(潜在源贡献因子分析法)和CWT(权重浓度轨迹分析法),分析了大气污染区域传输对兰州市空气质量的影响,探讨了影响兰州市空气质量的污染物输送来源和可能的潜在源区.结果表明,在影响兰州市的气流轨迹中,污染轨迹多来自兰州市以西和以北方向,污染轨迹约占总轨迹的39.52%,说明外部污染物的输入对兰州市空气质量具有重要影响.其中,第3类轨迹(对应来向为西)的气团对兰州市的空气质量有较大的影响,该类轨迹虽仅占总轨迹的15.21%,但其中污染轨迹数占56.76%,是影响兰州市空气质量的主要传输路径;第4类轨迹(对应来向为东南)的气团最为清洁.研究显示,对兰州市空气质量影响最大的强潜在源区主要分布在青海共和盆地、兰州市本地及周边区域,中等强度潜在源区为内蒙古自治区南部、宁夏回族自治区及甘肃省河西走廊等地区. 相似文献