重庆市伏旱时空变化特征

利用1961—2008年重庆34个台站的逐日降水资料,采用主成分分析、旋转主成分分析等方法对重庆伏旱变化的时空特征进行了分析。结果表明：重庆中西部是伏旱高频区,约10年7遇,且多重伏旱。重庆伏旱的第1载荷向量场表明重庆伏旱变化具有很好的整体一致性。重庆伏旱空间异常可分为4个区,即西部区、东北部区、东南部区和中部区。西部伏旱在1960—1970年代最强,东北部伏旱在90年代最强,其次是70年代,中部伏旱在70年代最强,其次是2000年以后,东南部伏旱的年代际变化趋势不明显,且伏旱整体较轻。     

重庆市全域山系脉络梳理及划定工作研究

重庆属于典型的山地地貌类型,但全域山系脉络情况一直没有被全面而详细的梳理。本文研究利用DEM、遥感影像及其他相关资料,从生态角度出发,由下至上地提取重庆市域范围内山体、山脉,形成全市山系脉络基础本底,对重庆市山系生态保护范围的划定及定量化研究具有重要的理论和实践意义。     

《重庆历史地图集·第一卷古地图》设计与研制

文章介绍了该图集编制的背景及国内编纂情况,阐述了图集需遵循的设计原则和工艺流程,构思了图集每个版块的定位及内容组成。重点对图集在编纂过程中开本设计、结构设计、内容设计、排版和整饰设计等方面进行了剖析,并根据重庆本地历史文化展现的需要,进行了对应的设计。其中的结构编排设计、内容排版设计、图名设计、文字内容结构设计,及版式中使用的中华民族文化元素和重庆本地的文化元素的有机融合等方面,在同类作品中实现了多项创新。最后,分析总结了图集编纂中的问题和解决方法,为后续相关产品的设计与编制提供参考。     

“数字重庆”建设与发展初探

大力发展“数字重庆”建设,是充分发挥重庆独特的区位优势,实现社会生产力跨越式发展,推动重庆经济快速发展的最佳切入点,是跻身世界级城市的必由之路。本文结合重庆本地的实际情况,因地制宜,在“数字重庆”的建设方略与发展思路上进行了初探。     

Long-term hydrological,biogeochemical, and climatological data from Walker Branch Watershed,East Tennessee,USA

In 1967, the original Walker Branch Watershed (WBW) project was established to study elemental cycling and mass balances in a relatively unimpacted watershed. Over the next 50+ years, findings from additional experimental studies and long-term observations on WBW advanced understanding of catchment hydrology, biogeochemistry, and ecology and established WBW as a seminal site for catchment science. The 97.5-ha WBW is located in East Tennessee, USA, on the U.S. Department of Energy's Oak Ridge Reservation. Vegetation on the watershed is characteristic of an eastern deciduous, second-growth forest. The watershed is divided into two subcatchments: the West Fork (38.4 ha) and the East Fork (59.1 ha). Headwater streams draining these subcatchments are fed by multiple springs, and thus flow is perennial. Stream water is high in base cations due to weathering of dolomite bedrock and nutrient concentrations are low. Long-term observations of climate, hydrology, and biogeochemistry include daily (1969–2014) and 15-min (1994–2014) stream discharge and annual runoff (1969–2014); hourly, daily, and annual rainfall (1969–2012); daily climate and soil temperature (1993–2010); and weekly stream water chemistry (1989–2013). These long-term datasets are publicly available on the WBW website (https://walkerbranch.ornl.gov/long-term-data/ ). While collection of these data has ceased, related long-term measurements continue through the National Ecological Observatory Network (NEON), where WBW is the core terrestrial and aquatic site in the Appalachian and Cumberland Plateau region (NEON's Domain 7) of the United States. These long-term datasets have been and will continue to be important in evaluating the influence of climatic and environmental drivers on catchment processes.     

Little River Experimental Watershed,a keystone in understanding of coastal plain watersheds

The US Department of Agriculture-Agricultural Research Service Southeast Watershed Research Laboratory (SEWRL) initiated a hydrologic research program on the Little River Experimental Watershed (LREW) in 1967. Long-term (52 years) streamflow data are available for nine sites, including rainfall-runoff relationships and hydrograph characteristics regularly used in research on interactive effects of climate, vegetation, soils, and land-use in low-gradient streams of the US EPA Level III Southeastern Plains ecoregion. A summary of prior research on the LREW illustrates the impact of the watershed on building a regional understanding of hydrology and water quality. Climatic and streamflow data were used to make comparisons of scale across the nine nested LREW watersheds (LRB, LRF, LRI, LRJ, LRK, LRO, LRN, LRM, and LRO3) and two regional watersheds (Alapaha and Little River at Adel). Annual rainfall for the largest LREW, LRB, was 1200 mm while average annual streamflow was 320 mm. Annual rainfall, streamflow, and the ratio between annual streamflow and rainfall (Sratio) were similar (α = 0.05) across LREWs LRB, LRF, LRI, LRJ, LRK, and LRO. While annual rainfall within the 275 ha LRO3 was found to be similar to LRO and LRM (α = 0.05), annual streamflow and Sratio were significantly different (α = 0.05). Comparisons of annual rainfall, streamflow, and Sratio between LRB and the regional watersheds indicated no differences (α = 0.05). Based upon this analysis, most regional watersheds shared similar hydrologic characteristics. LRO3 was an exception, where increases in row crops and decreases in forest coverage resulted in increased streamflow. LREW data have been instrumental in building considerable scientific understanding of flow and transport processes for these stream systems. Continued operation of the LREW hydrologic network will support hydrologic research as well as environmental quality and riparian research programs that address emerging and high priority natural resource and environmental issues.     

High-resolution climate variability of southwest China during 57-70 ka reflected in a stalagmite δ18O record from Xinya Cave

A 26-cm-long stalagmite (XY2) from Xinya Cave in northeastern Chongqing of China has been ICP-MS ²³⁰Th/U dated, showing a depositional hiatus at 2.3 cm depth from the top. The growth of the 2.3–26 cm interval determined by four dates was between 57 ka and 70 ka, with a linear growth rate of 0.023 mm/a. We have analyzed 190 samples for δ ¹⁸O and δ ¹³C, mostly in the 2.3–26 cm part. The δ ¹⁸O and δ ¹³C values between 57 ka and 70 ka reveal decadal-to-centennial climatic variability during the glacial interval of Marine Isotope Stage 4 (MIS4), exhibiting much higher resolution than that of the published Hulu and Dongge records during this interval. Speleothem δ ¹⁸O in eastern China, including our study area can be used as a proxy of summer monsoon strength, with lighter values pointing to stronger summer monsoon and higher precipitation, and vice versa. Two decreases in the δ ¹⁸O signature of XY2 record around 59.5 and 64.5 Ka are argued to correspond to the Dansgaard-Oeschger (D-O) events 17 and 18 respectively. The Heinrich event 6 (H6) can be identified in the record as a heavy δ ¹⁸O peak around 60 ka, indicating significant weakening of the monsoon in Chongqing during the cold period. The XY2 δ ¹⁸O record shows very rapid change toward to the interstadial condition of the D-O event, but more gradual change toward to the cold stadial condition. This phenomenon found in the Greenland ice core records is rarely observed so clearly in previously published speleothem records. According to SPECMAP δ ¹⁸O record, the glacial maximum of MIS 4 was around 64.5 ka with the boundary of MIS 3/4 around 60 ka. Unlike the marine record, the speleothem record of XY2, China, exhibits much high frequency variations without an apparent glacial maximum during MIS 4. However, the timing of MIS 3/4 boundary seems to be around 60 ka when the H6 terminated, in agreement with the marine chronology. The growth period of sample XY2 during glacial times probably reflects a local karstic routing of water, rather than having climatic significance. Supported by the National Natural Science Foundation of China (Grant Nos. 40672165, 90511004, 40672202) and the Academician Special Project of Chongqing Science Committee (Grant No. 2003-7835)     

岷县漳县6.6级地震后申都乡地窖宏观异常现象及其机理探讨

2013年7月22日甘肃岷县漳县M_s6.6地震后岷县申都乡某地窖出现冒白色烟雾的宏观异常现象。本文通过土壤气Rn、Hg现场检测和采样后气相色谱检测、生物显微镜观察结果,探讨了气体来源、赋存和运移机理以及异常形成的物理化学机制。认为该点具有灵敏的断层活动响应,可作为今后开展断层活动及未来甘东南地震趋势预测判定的断层土壤气监测点进行长期监测。     

重庆及邻区地震精定位研究

采用双差地震定位法,对2008年1月—2013年11月重庆及邻区的荣昌、綦江、石柱、巫山—湖北巴东、巫溪地区地震进行精定位。结果表明,重新定位后地震震源位置比常规地震定位法得到的结果更加精确。荣昌、綦江、石柱地区地震震中呈条带状分布较明显,与断裂构造一致性较好;巫山—巴东、巫溪地区地震震中成团现象明显,地震成因较复杂。     

利用剪切波分裂研究青藏高原东北缘及东南缘上地幔各向异性

利用从IRIS上下载的青藏高原东北缘238个台站以及中国地震科学探测台阵喜马拉雅一期350个台站记录到的远震波形数据,通过采用剪切波分裂方法,获取各个台站下方各向异性分裂参数——快波偏振方向（φ）和分裂时差（δt）,从而得到青藏高原东北缘、东南缘上地幔的各向异性特征。研究结果表明,祁连块体、阿拉善块体和鄂尔多斯块体北部,快波方向为NNW-SSE,明显不同于GPS测量得到的近NE-SW的地表位移场方向,延迟时间平均~0.85 s;羌塘块体以及松潘-甘孜褶皱带的西部,快波方向呈现沿顺时针方向旋转的趋势,并且与GPS测量得到的地表位移场方向一致,延迟时间平均为~1.24 s;松潘-甘孜褶皱带东部、秦岭造山带与鄂尔多斯块体南部的交界处,快波方向呈现无序分布,与GPS方向表现出不一致的分布,延迟时间平均~1.08 s;川滇块体北部,快波方向近似N-S方向,与GPS测量得到的地表位移场方向相同,平均延迟时间为~0.925 s;位于北纬26°以南的川滇块体南部,快波方向近E-W方向分布,明显不同于GPS地表位移场方向,平均延迟时间~1.065 s。综合分析推测,羌塘块体、松潘-甘孜褶皱带的西部以及川滇块体北部,地表形变和深部之间的变形是相互耦合的;祁连块体、阿拉善块体和鄂尔多斯块体北部,松潘-甘孜褶皱带东部、秦岭造山带与鄂尔多斯块体南部的交界处以及川滇块体南部,壳幔之间可能存在解耦现象。