近30年来长江源区土地覆被变化特征分析

长江源区是我国重要的水源涵养地。本文利用20世纪70年代中后期、90年代初期、2004年和2008年共4期土地覆被数据,通过土地覆被转类途径与幅度、土地覆被状况指数和土地覆被转类指数,分析评价了长江源区近30年来土地覆被与生态状况的时空变化特征。结果表明：草地是长江源区主要的土地覆被类型,2008年草地面积占该区总面积的66.93%。在70年代中后期-90年代初期、90年代初期-2004年和2004-2008年的3个时段内,土地覆被状况指数变化率分别为-0.15、-0.24和0.01;土地覆被转类指数分别为-0.20、-0.66和0.08。近30年来,长江源区土地覆被和生态状况总体经历了变差-显著变差-略有好转的过程。2004-2008年,长江源区年平均温度比前期（70年代中后期-2004年）升高了0.57℃,年平均降水量比前期增加了17.63mm。区域气候变化有助于自然生态系统的恢复。后期生态保护与建设工程的实施,对植被恢复产生了一定的积极作用。     

煤炭革命新理念与煤炭科技发展构想

为探索采动影响下的断层活化突水机理,开展断层破碎岩体剪切变形与渗透性演化试验研究。基于流固耦合原理设计一套破碎岩体压剪渗流试验系统,实现破碎岩体剪切变形与渗流的耦合过程,开展多因素影响下的破碎岩体剪切−渗流耦合试验,获得连续剪切过程中颗粒级配和初始孔隙率对孔隙率和渗透性参量的影响规律。结果表明,连续剪切条件下,破碎岩体的渗透率和孔隙率变化过程大致相同,可分为3个阶段：缓慢增长阶段,破碎岩石颗粒由散乱状态向有序的组织结构调整;加速增长阶段,破碎岩石颗粒剪切膨胀;增速放缓阶段,破碎岩体颗粒的剪切变形在围压的约束下达到动态平衡。试样Talbot指数越小或初始孔隙率越大,渗透率和孔隙率敏感性越强,渗透率和孔隙率越大;非Darcy流β因子的演化规律与渗透率的演化规律相反。结合数值模拟发现,剪切作用下破碎岩体剪切带内岩石颗粒的运移是剪胀现象发生的主要原因,破碎岩体剪胀过程中颗粒的力链由随机分布向特定方向转化,表现为局部孔隙和孔喉的膨胀,是孔隙率和渗透率增加的主要原因。研究成果可为深部煤矿突水灾害机理揭示与灾害防治提供参考。

     

黑龙江省干旱及植被分布的时空变化分析

干旱是影响社会经济系统和自然生态系统的重要气象灾害.本研究基于多时间序列的SPEI和NDVI栅格数据,利用GIS空间分析方法和统计分析方法,对比分析了2000—2018年黑龙江省干旱和植被分布的时空变化特征,从而揭示了干旱对植被分布的影响.研究表明:1)干旱具有明显的年际和季节特征,以及干湿变化的阶段性和趋势性,呈东—西干湿反向变化空间分布;2)植被分布具有明显季节特征,但年际特征不明显,呈西北、北部和东南部高,东北、西南部低的空间分布;3)干旱对植被分布影响具有复杂性.研究结果可为干旱防灾减灾和影响评估以及区域生态恢复提供参考依据.     

浅谈计算机技术在煤矿储量估算中的应用

介绍了在煤矿储量估算中应用Microsoft Excel制作各种表格及计算,同时应用MAPGIS软件直接绘制储量估算图,提高图件的精度及节省绘制图件的时间。     

阿拉善高原近60年的气候变化

阿拉善高原处于季风边缘区,生态环境极其脆弱,对气候干湿变化的响应极为敏感。利用近60a的逐月气温和降水量资料,采用非参数Mann-Kendall和Mann-whitney阶段性转换检验方法,分析了其变化趋势。结果表明,研究区气温在1988年前后发生突变,在该跃点后的19882010年的平均气温比19551987年要高1℃以上,有明显的增温趋势。而年降水量则无明显的增加趋势,尽管部分站点在1991年前后有微弱的增加迹象,但是区域尺度的降水突变还不存在,气候仍以暖干化为主,暂不能得出气候向暖湿转变的结论。     

YTT事件在洛川黄土中的记录:来自固定铵和速效钾的证据

Toba火山活动是第四纪最大的火山事件,其中最年轻的约0．074Ma的火山活动被称为YTT事件（The Youngest Toba Tuff）。已有的研究表明,YTT事件对第四纪的环境气候变化具有重要的影响,黄土S1／L1界面处的磁化率和粒度等因子突变所反映的夏季风迅速回撤可能响应了这一事件。对洛川黄土S1／L1界面处的固定铵和速效钾进行了研究,结果表明,YTT在洛川黄土S1／L1界面处有很清楚的记录,具体表现为固定铵和速效钾的特殊异常。固定铵的异常主要记录了YTT事件所产生的酸雨沉降,速效钾的异常则是由于YTT微细火山灰尘在黄土剖面及其广阔的物源区伴随酸雨沉降的结果,厚达1m的异常带表明末次冰期冬季风逐渐强盛和南移的过程。     

The multi-component Hekla Ö Tephra,Iceland: a complex widespread mid-Holocene tephra layer

Large Plinian eruptions from Hekla volcano, Iceland, produce compositionally zoned tephra used as key markers in tephrochronology. However, spatial variations in chemical composition of a tephra layer may complicate its identification. An example is the 5950–6180 cal a bp Hekla Ö tephra layer, which shows compositional spread from rhyolite, dacite and andesite to basalt. In soil sections north of Hekla, the SiO₂ content of the tephra glass reaches 76 wt% in the lowest unit of the Hekla Ö deposit and decreases to 62–63 wt% in the uppermost unit. Intermingled within the whole deposit are basalt tephra grains having 46–47 wt% SiO₂. The composition of the basalt glass includes primitive basalt and a more evolved basalt (MgO >6 and <6 wt%, respectively). Together with literature data, the Hekla Ö tephra and the so-called T-Tephra/Hekla-T are most likely from contemporaneous eruptions of different vents on the Hekla volcanic system, forming a single important marker tephra (Hekla ÖT) deposited over 80% of Iceland. Identification is complicated by its spatial compositional heterogeneity, such as systematic decrease in SiO₂ content from the east to the west of Hekla volcano. Consequently, an individual tephra layer from a large explosive eruption can have different composition at different locations. © 2020 John Wiley & Sons, Ltd.     

Differential Thermal Regimes of the Tarim and Sichuan Basins in China: Implications for Hydrocarbon Generation and Conservation

The uncertainty surrounding the thermal regimes of the ultra-deep strata in the Tarim and Sichuan basins, China, is unfavorable for further hydrocarbon exploration. This study summarizes and contrasts the present-day and paleo heat flow, geothermal gradient and deep formation temperatures of the Tarim and Sichuan basins. The average heat flow of the Tarim and Sichuan basins are 42.5 ± 7.6 mW/m2 and 53.8 ± 7.6 mW/m2, respectively, reflecting the characteristics of ‘cold’ and ‘warm’ basins. The geothermal gradient with unified depths of 0–5,000 m, 0–6,000 m and 0–7,000 m in the Tarim Basin are 21.6 ± 2.9 °C/km, 20.5 ± 2.8 °C/km and 19.6 ± 2.8 °C/km, respectively, while the geothermal gradient with unified depths of 0–5,000 m, 0–6,000m and 0–7,000 m in the Sichuan Basin are 21.9 ± 2.3 °C/km, 22.1 ± 2.5 °C/km and 23.3 ± 2.4 °C/km, respectively. The differential change of the geothermal gradient between the Tarim and Sichuan basins with depth probably results from the rock thermal conductivity and heat production rate. The formation temperatures at depths of 6,000 m, 7,000 m, 8,000 m, 9,000 m and 10,000 m in the Tarim Basin are 80°C–190°C, 90°C–220°C, 100°C–230°C, 110°C–240°C and 120°C–250°C, respectively, while the formation temperatures at depths of 6,000 m, 7,000 m, 8,000 m and 9,000 m in the Sichuan Basin are 120°C–200°C, 140°C–210°C, 160°C–260°C and 180°C–280°C, respectively. The horizontal distribution pattern of the ultra-deep formation temperatures in the Tarim and Sichuan basins is mainly affected by the basement relief, fault activity and hydrothermal upwelling. The thermal modeling revealed that the paleo-heat flow in the interior of the Tarim Basin decreased since the early Cambrian with an early Permian abrupt peak, while that in the Sichuan Basin experienced three stages of steady state from Cambrian to early Permian, rapidly rising at the end of the early Permian and declining since the late Permian. The thermal regime of the Sichuan Basin was always higher than that of the Tarim Basin, which results in differential oil and gas generation and conservation in the ultra-deep ancient strata. This study not only promotes theoretical development in the exploration of ultra-deep geothermal fields, but also plays an important role in determining the maturation phase of the ultra-deep source rocks and the occurrence state of hydrocarbons in the Tarim and Sichuan basins.