新疆伊吾韧性剪切带的发现及其成矿地质作用探讨

新疆伊吾韧性剪切带变形组构较发育,序列演化明显,存在逆冲剪切和韧—脆性变形转换,变形时代为华力西早期,早于晚二叠世。其形成时代应早于研究区岩浆侵入活动时期。变形机制属地壳中深层次塑性流变和韧性剪切,经历了多期多阶段演变等特征。该剪切带控制了该区的成矿带、矿化带、矿体的产状。对中—低温热液金银铜等主要矿产的成矿作用和分布规律作了初步探讨,粗略判断成矿过程大概是在地质事件多发的晚古生代,并且成矿具多期性和多源性。     

A full-scale field experiment to study the thermal-deformation process of widening highway embankments in permafrost regions

As one of the widely used upgrading way in road engineering, the widening embankment(WE) has suffered evident differential deformation, which is even severer for highway in permafrost regions due to the temperature sensitivity of frozen soil and the heat absorption effect of the asphalt pavement. Given this issue, a full-scale experimental highway of WE was performed along the Qinghai-Tibet Highway(QTH) to investigate the differential deformation features and its developing law. The continuous three years' monitoring data taken from the experimental site, including the ground temperature and the layered deformation of WE and original embankment(OE), were used to analyze the thermal-deformation process. The results indicate that the widening part presented the remarkable thermal disturbance to the existing embankment(EE). The underlying permafrost was in a noteworthy degradation state, embodying the apparent decrease of the permafrost table and the increase of the ground temperature. Correspondingly, the heat disruption induced by widening led to a much higher deformation at the widening side compared to the original embankment, showing a periodic stepwise curve. Specifically, the deformation mainly occurred in the junction of the EE and the widening part, most of which was caused by the thawing consolidation near the original permafrost table. In contrast, the deformation of EE mainly attributed to the compression of the active layer. Furthermore, it was the deformation origination differences that resulted in the differential deformation of WE developed gradually during the monitoring period, the maximum of which reached up to 64 mm.     

新疆开都河流域不同环境介质中的有机氯农药和多环芳烃残留及分布特征

为探讨新疆开都河流域水不同介质的来源及分布特征,检测了开都河流域水、土壤和表层沉积物样品中20种有机氯农药(OCPs)和16种多环芳烃(PAHs)的含量。结果显示,OCPs和PAHs在水中的含量分别为42.5~62.5ng/L和29.4~454.3ng/L,在土壤中的含量分别为8.8~12.4ng/g和6.6~128.2ng/g,在表层沉积物中的含量分别为6.6~13.7ng/g和20.8~491.0ng/g。空间分布上,开都河中游污染相对严重的土壤对应的周边河流沉积物也具有较高浓度的污染物,这种分布明显受人类活动影响,沿河道上游呈递增趋势,但总体上低于入湖口沉积物中的含量,表明博斯腾湖蓄积了来自周边的污染物。来源分析表明,开都河流域的六六六(HCHs)和滴滴涕(DDTs)主要是历史残留,而入湖口区水体和表层沉积物中新的DDTs,可能与湖泊沉积物被扰动引起的再悬浮释放有关。PAHs以低分子量组分为主,其高含量主要来自于木柴、煤等中低温燃烧。风险评价结果表明,开都河流域土壤和沉积物中的OCPs和PAHs不存在显著的生态风险。     

日本刺参的抗肿瘤及免疫调节作用研究

采用日本刺参（Apostichopus japonicus）浆灌胃移植性肿瘤模型小鼠,探讨了日本刺参的抗肿瘤作用及其对免疫功能的调节作用。结果表明,日本刺参各剂量组均能显著抑制小鼠S180肉瘤的生长,提高小鼠脾指数及胸腺指数（P〈0．05）;显著提高荷瘤小鼠血清溶血素含量（P〈0．01）和抗体形成细胞数（P〈0．05）;提高迟发型变态反应水平和脾淋巴细胞转化能力（P〈0．05,P〈0．01）;促进NK细胞活性和巨噬细胞的吞噬能力（P〈0．05。P〈0．01）。提示日本刺参能全面调节机体的特异性和非特异性免疫功能．控制和杀灭肿瘤细胞。     

Nitrate vertical transport and simulation in soils of rocky desertification in Karst regions,Southwest China

The characteristics of nitrate vertical transport in soils collected from Libo and Puding in Guizhou Province were studied by simulating soil column in laboratory. The results were as follows: (1) Vertical transport velocity of nitrate decreased, and the breakthrough curves (BTCs) of nitrate were more dispersed, in each horizon from surface layer to bottom layer in every soil profile. As rocky desertification progressed, the BTCs experienced a gentle up and down trend, and tailing was more obvious. (2) An analytical solute transport model (CXTFIT 2.0) was used to estimate nitrate dispersion coefficient (D) and average pore water velocity (V) from the observed BTCs. The results showed that CXTFIT 2.0 model was suitable in fitting the nitrate transport in these soils. The dispersion coefficient was found to be a function of average pore water velocity. (3) The transport of nitrate was mainly affected by the soil structural coefficient. As soil structural coefficient decreased, nitrate outflow was retarded, and the peak concentration was reduced. Soil bulk density, organic matter, and clay also affected the vertical transport of nitrate. Low bulk density, clay content, and high organic matter content were each associated with faster nitrate transport.     

HORIZONTAL MOVEMENT CHARACTERISTICS OF THE ACTIVE SANWEISHAN FAULT AND ITS MECHANISM: CONSTRAINTS ON THE GROWTH OF THE NORTHERN QINGHAI-TIBETAN PLATEAU

The northern margin of the Qinghai-Tibet Plateau is currently the leading edge of uplift and expansion of the plateau. Over the years, a lot of research has been carried out on the deformation and evolution of the northeastern margin of the Qinghai-Tibet Plateau, and many ideas have been put forward, but there are also many disputes. The Altyn Tagh Fault constitutes the northern boundary of the Qinghai-Tibet Plateau, and there are two active faults on the north side of the Altyn Tagh Fault, named Sanweishan Fault with NEE strike and Nanjieshan Fault with EW strike. Especially, studies on the geometric and kinematic parameters of Sanweishan Fault since the Late Quaternary, which is nearly parallel with the Altyn Tagn Fault, are of great significance for understanding the deformation transfer and distribution in the northwestward extension of the Qinghai-Tibet Plateau. Therefore, interpretation of the fault landforms and statistical analysis of the horizontal displacement on the Sanweishan Fault and its newly discovered western extension are carried out in this paper. We believe that the Sanweishan Fault is an important branch of the eastern section of the Altyn Tagh fault zone. It is located at the front edge of the northwestern Qinghai-Tibet Plateau and is a left-lateral strike-slip and thrust active fault. Based on the interpretation of satellite imagery and microgeomorphology field investigation of Sanweishan main fault and its western segments, it's been found that the Sanweishan main fault constitutes the contact boundary between the Sanweishan Mountain and the alluvial fans. In the bedrock interior and on the north side of the Mogao Grottoes, there are also some branch faults distributed nearly parallel to the main fault. The main fault is about 150km long, striking 65°, mainly dipping SE with dip angles from 50° to 70°. The main fault can be divided into three segments in the spatial geometric distribution:the western segment(Xizhuigou-Dongshuigou, I), which is about 35km long, the middle segment(Dongshuigou-Shigongkouzi, Ⅱ), about 65km long, and the east segment(Shigongkouzi-Shuangta, Ⅲ), about 50km long. The above three segments are arranged in the left or right stepovers. In the west of Mingshashan, it's been found that the fault scarps are distributed near Danghe Reservoir and Yangguan Town in the west of Minshashan Mountain, and we thought those scarps are the westward extension of the main Sanweishan Fault. Along the main fault and its western extension, the different levels of water system(including gullies and rills)and ridges have been offset synchronously, forming a series of fault micro-geomorphology. The scale of the offset water system is proportional to the horizontal displacement. The frequency statistical analysis of the horizontal displacement shows that the displacement has obvious grouping characteristics, which are divided into 6 groups, and the corresponding peaks are 3.4m, 6.7m, 11.4m, 15m, 22m and 26m, respectively. Among them, 3.4m represents the coseismic displacement of the latest ancient earthquake event, and the larger displacement peak represents the accumulation of coseismic displacements of multi-paleoearthquake events. This kind of displacement characterized by approximately equal interval increase indicates that the Sanweishan Fault has experienced multiple characteristic earthquakes since the Late Quaternary and has the possibility of occurrence of earthquakes greater than magnitude 7. The distribution of displacement and structural transformation of the end of the fault indicate that Sanweishan Fault is an "Altyn Tagh Fault"in its infancy. The activities of Sanweishan Fault and its accompanying mountain uplift are the result of the transpression of the northern margin of the Qinghai-Tibet Plateau, representing one of the growth patterns of the northern margin of the plateau.     

基于KPCA的台风强度神经网络集合预报方法研究

针对影响台风强度前期预报因子较多以及因子的非线性变化特点,首先采用逐步回归方法筛选出部分预报因子,再利用核主成分分析方法在剩余的预报因子中提取包含了原数据较多信息的核主成分与前期选入的预报因子共同作为模型输入.进一步考虑到神经网络集合预报中个体的准确性和差异性的权衡问题,在不同的初始条件下生成若干组神经网络,分别选择每组中性能最优的个体,建立了一种新的非线性神经网络集合预报模型.最后以西北太平洋海域2001-2010年5-10月的台风强度为研究对象进行了预报试验.结果表明,这种神经网络集合预报模型的预报结果符合实际应用的要求,其预报平均绝对误差明显小于同等条件下的神经网络方法和逐步回归预报方法.     

京津冀地区AOD时空变化及影响因子的地理探测

基于MODIS 3 km AOD遥感数据,利用空间自相关模型及地理探测器对2010—2016年京津冀地区AOD的时空变化特征及其影响因子进行探测。结果表明:(1) 2010—2016年京津冀地区年平均AOD值为0.83,其中天津市年均AOD值为研究区最高,河北省次之,北京市最低。研究区及各分区AOD的7 a变化趋势大体一致,呈现先下降后上升再小幅波动的状态。(2)空间自相关分析表明京津冀地区AOD空间分布呈现显著正相关。局部高高聚集区主要集中在北京市东南部、天津市南部及河北省的中南部,低低聚集区集中分布在西北部山区。研究区高低聚集区面积均呈减小趋势,不显著区呈扩大态势。(3)地理探测器结果表明不同区域的主导影响因子不同,北京市首要影响因子为NDVI,其次为人口密度,且二者交互作用明显。天津市主导因子为风速,人口密度、第二产业生产总值等人为因子的作用力也较大,风速与其交互作用较强。河北省主导因子为人口密度,GDP与第二产业生产总值等的作用力次之,整体交互作用偏弱。通过地理探测器解析京津冀地区AOD空间分异的影响机理,其结果对我国大气污染治理具有重要意义。     

Discussion on the Use of 7Be to Estimate Soil Erosion Rates

⁷Be is a naturally occurring cosmogenic radionuclide produced in the stratosphere and troposphere as a result of cosmic ray spallation of nitrogen and oxygen. The constant fallout via precipitation and short half-life (53.3 days), coupled with shallow depth distribution in soil profile (~2 cm) provide the unique advantages for its application as a soil and sediment tracer over short timescales, such as a single storm or short period of extreme rainfall. With the climate change and increasing rainfall events, the ⁷Be tracing method will exhibit wide application prospect in future. To date, however, this technique is still in its infancy and some important assumptions have not yet been effectively validated. Consequently, the use of ⁷Be to document soil erosion rates has been limited. This contribution briefly reviews the history and current status relating to this tracing method. In addition, the basic principles and recent research progresses in conversion models for use of ⁷Be measurements to estimate soil redistribution rates are introduced. The key assumptions and uncertainties of the technique, as well as the effects of the vegetation interception and particle size selectivity are discussed. Additionally, some new investigation directions are provided, including the assumption validation and uncertainty analysis, the impact of vegetation interception, the extending of spatial and temporal scales, and the development of new conversion models.