论著获奖 |
(一)近期代表性论文 [1]Zhang Miao, Chen Luwang*, Yao Duoxi, Hou Xiaowei, Zhang Jie, Qin Hao, Ren Xingxing, Zheng Xin. Hydrogeochemical processes and inverse modeling for a multilayer aquifer system in the Yuaner coal mine, Huaibei coalfield, China[J]. Mine Water and the Environment, 2022. (网络出版, SCI收录, DOI: 10.1007/s10230-022-00851-0.) [2]Zhang Jie, Chen Luwang*, Hou Xiaowei, Ren Xingxing, Li Jun, Chen Yifei. Hydrogeochemical processes of Carboniferous limestone groundwater in the Yangzhuang coal mine, Huaibei coalfield, China[J]. Mine Water and the Environment. 2022,41(2):504-517.(SCI收录) [3]Li Jun, Gui Herong, Chen Luwang*,Fang Pei, Li Xiaoping, Zhang Jie, Wang Yingxin. Geochemistry of upper Palaeozoic 'thin-layer' limestones in the southern North China Craton: implications for closure of the northeastern Palaeotethys Ocean[J]. Geological Magazine, 2022, 159(4):494-510. (SCI收录) [4]Zhang Jie, Chen Luwang*, Hou Xiaowei, Li Jun, Ren Xingxing, Lin Manli, Zhang Miao, Wang Yingxin, Tian Yue. Effects of multi-factors on the spatiotemporal variations of deep confined groundwater in coal mining regions, North China[J]. Science of the Total Environment, 2022,823:153741. (SCI收录) [5]Chen Luwang, Ou Qinghua, Peng Zhihong, Wang Yingxin, Chen Yifei, Tian Yue. Numerical simulation of abnormal roof water-inrush mechanism in mining under unconsolidated aquifer based on overburden dynamic damage[J]. Engineering Failure Analysis, 2022, 133:106005. (SCI收录) [6]Zhang Jie, Chen Luwang*, Hou Xiaowei, Lin Manli, Ren Xingxing, Li Jun, Zhang Miao, Zheng Xin. Multi-isotopes and hydrochemistry combined to reveal the major factors affecting Carboniferous groundwater evolution in the Huaibei coalfield, North China[J]. Science of the Total Environment, 2021,791:148420. (SCI收录) [7]Ma Haichun, Chen Luwang, Tan Xiaohui, Qian Jiazhong, Lu Zhitang. Theoretical dynamic displacement analysis for rock bolt with surrounding rock-soil body[J]. International Journal of Rock Mechanics and Mining Sciences, 2021, 141:104698. (SCI收录) [8]Li Jun, Gui Herong, Chen Luwang*, Fang Pei, Li Guangping, Li Ruirui. Geochemical characteristics, palaeoenvironment, and provenance of marine mudstone in Shanxi Formation of Huaibei Coalfield, southern North China Plate[J]. Geological Journal, 2021, 56(6):3064-3080. (SCI收录) [9]Zhang Jie, Chen Luwang*, Li Jun, Chen Yifei, Ren Xingxing, Shi Xiaoping. Analysis of mining effects on the geochemical evolution of groundwater, Huaibei coalfield, China[J]. Environmental Earth Sciences, 2021, 80(03): 98. (SCI收录) [10]Peng Zhihong, Chen Luwang*, Hou Xiaowei, Ou Qinghua, Zhang Jie, Chen Yifei. Risk Assessment of water inrush under an unconsolidated, confined aquifer: the application of GIS and information value model in the Qidong Coal Mine, China[J]. Earth Science Informatics, 2021,14(4): 2373-2386. (SCI收录) [11]Chen Luwang, Li Ruirui, Wang Lanting, Zhang Jie, Ou Qinghua, Ren Xingxing, Zhou Kandong. Microfracture development and chemical damage analysis of limestone based on fractal theory[J]. Quarterly Journal of Engineering Geology and Hydrogeology, 2021, 54(3): qjegh2020-015. (SCI收录) [12]Jie Zhang, Luwang Chen*, Yifei Chen, Rutao Ge, Lei Ma, Kandong Zhou, Xiaoping Shi. Discrimination of water-inrush source and evolution analysis of hydrochemical environment under mining in Renlou coal mine, Anhui Province, China[J]. Environmental Earth Sciences, 2020, 79: 61. (SCI收录) [13]Luwang Chen, Xiaoqing Feng, Dongqing Xu, Wen Zeng, Zhiyuan Zheng. Prediction of water inrush areas under an unconsolidated, confined aquifer: the application of the multi-information superposition based on GIS and AHP in the Qidong coal mine, China[J]. Mine water and the Environment, 2018, 37(4): 786-795. (SCI收录) [14]Luwang Chen, Shengjie Li, Kaixian Zhang, Yanxian Liu. Secondary development and application of the NP-T creep model based on FLAC3D[J]. Arabian Journal of Geosciences, 2017, 10: 508. (SCI收录) [15]Luwang Chen, Xiaoqing Feng, Wenping Xie, Wen Zeng, Zhiyuan Zheng. Using a fluid-solid coupled numerical simulation to determine a suitable size for barrier pillars when mining shallow coal seams beneath an unconsolidated, confined aquifer[J]. Mine water and the Environment, 2017, 36(1): 67-77. (SCI收录) [16]Chen Luwang, Xie Wenping, Feng Xiaoqing, Zhang Nengqin, Yin Xiaoxi. Formation of hydrochemical composition and spatio-temporal evolution mechanism under mining-induced disturbance in the Linhuan coal-mining district[J]. Arabian Journal of Geosciences, 2017, 10: 57. (SCI收录) [17]Luwang Chen, Xiaoqing Feng, Wenping Xie, Dongqing Xu. Prediction of water-inrush risk areas in process of mining under the unconsolidated and confined aquifer: a case study from the Qidong coal mine in China[J]. Environmental Earth Sciences, 2016, 75: 706. (SCI收录) [18]Yin Xiaoxi, Chen Luwang*, He Jiandong, Feng Xiaoqing, Zeng Wen. Characteristics of groundwater flow field after land creation engineering in the hilly and gully area of the Loess Plateau, Arabian Journal of Geosciences, 2016, 9: 646. (SCI收录) [19]Chen Luwang, Bai Shiwei, Yin Xiaoxi. Physical simulation on failure around a circular cavern in hard and brittle rock under high and increasing natural stress conditions[J]. Journal of Engineering Mechancis-ASCE, 2014, 140(2): 332-344. (SCI收录) [20]Chen Luwang, Yin Xiaoxi, Xie Wenpin, Feng Xiaoqing. Calculating groundwater mixing ratios in groundwater inrushing aquifers based on environmental stable isotopes (D, 18O) and hydrogeochemistry[J]. Natural Hazards, 2014, 71: 937-953. (SCI收录) [21]Chen Luwang, Zhang Shilei, Gui Herong. Prevention of water and quicksand inrush during extracting contiguous coal seams under the lowermost aquifer in the unconsolidated Cenozoic alluvium—a case study[J]. Arabian Journal of Geosciences, 2014, 7: 2139-2149. (SCI收录) [22]陈陆望, 任星星, 张杰, 陈逸飞, 郑忻. 淮北煤田太原组灰岩水水文地球化学形成作用及反向模拟研究[J]. 煤炭学报, 2021, 46(12): 3999-4009. [23]陈陆望, 王迎新, 欧庆华, 彭智宏, 陈逸飞, 李蕊瑞. 考虑覆岩结构影响的近松散层开采导水裂隙带发育高度预测模型研究——以淮北煤田为例[J]. 工程地质学报, 2021, 29(04): 1048-1056. [24]陈陆望, 彭智宏, 王迎新, 葛如涛, 李蕊瑞. 松散承压含水层渗透系数变化规律与估算模型研究[J]. 煤田地质与勘探, 2021, 49(01): 189-197. [25]李蕊瑞, 陈陆望*, 欧庆华, 陈逸飞, 王迎新, 葛如涛, 彭智宏. 考虑覆岩原生裂隙的导水裂隙带模拟[J]. 煤田地质与勘探, 2020, 48(06): 179-185. [26]陈陆望, 李圣杰, 陈逸飞, 张开弦, 刘延娴. 岩石含水蠕变损伤模型的开发与应用[J]. 固体力学学报, 2018, 39(6): 642-651. [27]陈陆望, 许冬淸, 殷晓曦, 谢文苹, 曾文. 华北隐伏型煤矿区地下水化学及其控制因素分析——以宿县矿区主要突水含水层为例[J]. 煤炭学报, 2017, 42(4): 996-1004. (《煤炭学报》年度优秀论文) [28]陈陆望, 孙瑞, 白世伟, 冒海军, 刘金龙. 近地表倾斜矿体开采地表及覆岩变形破坏模拟[J]. 采矿与安全工程学报, 2014, 31(2): 243-248. (EI收录) [29]陈陆望, 殷晓曦, 桂和荣, 王茜. 矿区深部含水层水-岩作用的同位素与水化学示踪分析[J]. 地质学报, 2013, 87(7): 1021-1029. (二)专著与教材 [1]桂和荣, 陈陆望. 矿区地下水水文地球化学演化与识别[M]. 北京:地质出版社, 2007. [2]顾慰祖主编(著), 陈陆望参编(著). 同位素水文学[M]. 北京:科学出版社, 2011. [3]崔可锐主编, 陈陆望参编. 水文地质学基础[M]. 合肥:BETVlCTOR 伟德体育出版社, 2010. [4]武强主编, 赵苏启/李竞生副主编, 陈陆望参编. 煤矿防治水手册[M]. 北京:煤炭工业出版社, 2013. [5]桂和荣, 陈陆望. 厚松散层覆盖区浅部煤层开采防水防砂技术研究[M]. 徐州:中国矿业大学出版社, 2015. (三)近期代表性发明专利、软件著作权与标准 [1]陈陆望, 张杰, 任星星, 彭智宏, 陈逸飞, 郑忻. 基于常规水化学的煤矿突水水源混合比例计算及动态监测方法. CN 202011138892.3. [2]陈陆望, 王迎新, 胡杰, 葛如涛, 许帮贵, 赵杰, 何登云, 陆青山, 彭智宏. 一种松散承压含水层区域富水性动态确定方法. CN 202010976794.0. [3]陈陆望, 彭智宏, 倪建明, 胡杰, 王迎新, 许帮贵, 赵杰, 何登云, 陆青山, 葛如涛. 基于煤矿地质钻孔的松散承压含水层渗透系数确定方法. CN 202010976801.7. [4]陈陆望, 彭智宏, 欧庆华, 王迎新, 陈逸飞, 李蕊瑞. 一种松散承压含水层下开采突水危险性评价方法. CN 202011260084.4. [5]陈陆望, 王迎新, 欧庆华, 彭智宏, 陈逸飞. 基于覆岩结构的近松散层开采导水裂隙带高度确定方法. CN 202110165057.7. [6]陈陆望, 欧庆华, 陈逸飞, 张杰. 松散含水层下开采覆岩动力损伤破坏模拟计算软件V1.0. 授权时间: 2021/09/18, 授权号: 2021SR1403226. [7]陈陆望, 谢文苹, 曾文, 殷晓曦. 矿区地下水化学演化识别系统. 授权时间: 2015/07/10, 授权号: 2015SR130085. [8]计承富, 吴玉华, 陈陆望, 等. 煤矿充水水源氢氧稳定同位素示踪技术规范. 发布时间:2019-12-30, 标准号: NB/T 10381-2019. (四)奖励情况 [1]孔一凡, 桂和荣, 陈陆望, 洪荒, 殷晓曦, 傅昆岚, 付翔, 谢文苹, 冯晓青. 高承压强渗流松散含水层下安全开采防治水关键技术研究及应用. 中国煤炭工业科学技术三等奖, 2015. [2]葛春贵, 吴基文, 李文平, 倪建明, 胡宝林, 李书奎, 许帮贵, 赵成喜, 王新琨, 孙尚云, 胡德文, 孙如华, 陈陆望. 基于矿井地质保障系统研究的煤矿安全高效开采实践. 中国煤炭工业科学技术二等奖, 2013. [3]葛春贵, 陈陆望, 陈贵, 姚曹节, 刘晓宝, 王和志, 韩东亚, 许帮贵, 王大设. 采动影响下矿区充水含水层水文地球化学演化机理与水源识别技术. 中国煤炭工业科学技术三等奖, 2012. [4]吴玉华, 桂和荣, 陈陆望, 孙本魁, 洪荒, 易德礼. 厚松散层覆盖区浅部煤层开采的溃水溃砂机理与防治技术. 安徽省科学技术三等奖, 2011. [5]桂和荣, 李伟, 吴玉华, 宋庆尧, 程真富, 陈陆望, 胡德文, 程新明, 王和志. 厚松散层及超薄覆岩下回收防水(砂)煤柱资源防水防砂关键技术研究. 中国煤炭工业科学技术三等奖, 2008. [6]陈陆望.伟德bv1946官网伟德bv1946官网青年教师讲课比赛一等奖, 2008. [7]陈陆望.伟德bv1946官网伟德bv1946官网“就业支持奖”, 2010. [8]陈陆望.BETVlCTOR 伟德体育本科生毕业论文(设计)优秀指导教师, 2012. [9]陈陆望.BETVlCTOR 伟德体育本科生毕业论文(设计)优秀指导教师, 2016. [10]陈陆望.伟德bv1946官网伟德bv1946官网第一届“最具影响力”优秀教师, 2016.
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