基于物质量评估的贵州南部地区生态系统服务及其县域差异比较

以贵州南部地区为例,对涵养水源、固碳释氧、净化大气环境、保育土壤和生物多样性保护5个功能类别共14项指标的生态系统服务物质量进行了区域尺度和县域尺度上的估算。结果表明：① 贵州南部地区林草生态系统年调节水量145.41×10⁸m³,年固碳量和年释氧量分别为819.96×10⁴t和1 538.48×10⁴t,年提供负离子达2.32×10²⁵个,年吸收二氧化硫(SO₂)、氟化物(F)、氮氧化物(NO_X)分别达到58.07×10⁴t、1.29×10⁴t和7.76×10⁴t,年滞尘量1.04×10⁸t,年固土总量9.07×10⁸t,年保育N、P、K以及有机质量分别为184.81×10⁴t、59.26×10⁴t、1 138.80×10⁴t以及4 045.85×10⁴t,平均生物多样性综合评价指数为54.87;② 各类生态系统服务物质量均表现出明显的空间分布趋势,整体表现为东高西低,南高北低;③ 县域尺度上,黎平县、榕江县、从江县和望谟县提供的生态系统服务物质量最多,普定县、三穗县、长顺县和丹寨县则最少;就生态系统服务供给能力而言,雷山县、望谟县、榕江县和从江县最强,兴仁县、普定县、长顺县和贞丰县则最弱。     

近30年来长江源区与黄河源区土地覆被及其变化对比分析

基于20 世纪70 年代中后期、90 年代初期、2004 年和2012年共4 期土地覆被数据,利用转移矩阵、土地覆被状况指数和土地覆被转类指数,对比分析了长江源区和黄河源区近30 a来土地覆被与生态状况的变化特征。结果表明：2012年草地是两源区最主要的土地覆被类型,但黄河源区的草地面积占比比长江源区高17%,同时,长江源区存在永久冰川雪地及荒漠,黄河源区没有;从土地覆被状况来看,过去30 a黄河源区优于长江源区,长江源区土地覆被状况指数平均为16.82%,黄河源区为38.84%;从土地覆被转类来看,过去30 a长江源区土地覆被总体变好,黄河源区则总体变差,在20世纪70年代中后期至90年代初、20世纪90年代初至2004年和2004~2012年3时段内,长江源区土地覆被经历了变差-好转-持续好转的变化过程,而黄河源区则是变差-显著变差-略有好转,且黄河源区土地覆被状况的变化程度较长江源区更为剧烈;长江源区因分布有大量的冰川、冻土,自20世纪90年代气温升高开始,冰川冻土融化,导致水体与沼泽面积扩张,后期叠加生态工程的积极影响,使得其土地覆被状况持续好转,黄河源区则因2004 年以来暖湿的气候状况及生态保护工程的实施,使得土地覆被退化趋势得到遏制并逐渐呈现转好态势。     

植物叶片性状沿海拔梯度变化研究进展

由于在海拔梯度上各种环境因子表现出连续的梯度性变化,以海拔梯度为平台研究植物叶片性状的适应特征有助于揭示植物对气候变化的响应,进而可以为研究全球变化与陆地生态系统的关系提供研究基础。本文重点分析了植物的叶寿命、比叶面积、叶氮含量、叶绿素含量等叶片结构性状和气孔导度、叶片羧化效率、水分利用效率和叶片δ^18C等叶片功能性状随海拔梯度的变化规律和特点,探讨了植物叶片性状的研究不足及未来发展方向,以便为国内相关研究的开展提供参考。     

过去千年太阳活动异常期的中国东部旱涝格局

根据过去千年中国东部旱涝等级资料,采用各级旱涝发生几率的比率差指标,参照新近重建的5条过去千年太阳活动序列,重建了其间11个太阳活动异常期的中国东部旱涝格局。结果发现：在11个太阳活动异常期,中国东部旱涝格局各不相同。其中在5个太阳活动极小期（1010-1050年、1280-1350年、1460-1550年、1645-1715年、1795-1823年）,中国东部旱涝格局虽不一致,但长江中下游地区（华北地区）出现偏旱（涝）的几率更高;而在2个太阳活动极大期和4个太阳辐射高值期,中世纪极大（1100-1250年）整个东部多偏旱,1845-1873年的太阳辐射高值期,整个东部多偏涝;其余4个时段（1351-1387年、1593-1612年、1756-1787年、1920-2000年）则旱涝相间出现。集合平均表明：在太阳活动极小期,中国东部呈自南向北的“涝—旱—涝”分布：长江流域偏旱,南北两侧的华南沿海和华北平原偏涝,且西北东部及西南偏旱;而在太阳活动极大期和太阳辐射高值期,长江流域及西北东部多偏涝,华南和华北多偏旱。     

二论蒙阴地区金刚石原生矿的形成时代

目前不少学者认为,蒙阴地区金刚石原生矿形成于加里东期。然而这一观点,与依据多年来野外工作取得的实际资料所给出的结论不符。加里东期鲁西地区NW向断裂还不存在,NNE走向的上五井断裂更不会存在,这些晚于加里东的断裂不可能是金伯利岩储存的场所。大量金伯利岩岩脉、岩管的展布特点,岩体的完好程度,以及它们与上述断裂的相互关系,和金伯利岩切穿辉绿岩、斜长煌斑岩、正长斑岩等,都说明了金刚石原生矿的形成时代不是在加里东期,而是在中生代后期。     

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The marine dynamics and changing trend off the modern Yellow River mouth

Topography around the Yellow River mouth has changed greatly in recent years, but studies on the current state of ma- rine dynamics off the Yellow River mouth are relatively scarce. This paper uses a two-dimension numerical model(MIKE 21) to reveal the tidal and wave dynamics in 2012, and conducts comparative analysis of the changes from 1996 to 2012. The results show that M2 amphidromic point moved southeastward by 11 km. It further reveals that the tides around the Yellow River mouth are relatively stable due to the small variations in the tidal constituents. Over the study period, there is no noticeable change in the distribution of tidal types and tidal range, and the mean tidal range off the river mouth during the period studied is 0.5–1.1 m. However, the tidal currents changed greatly due to large change in topography. It is observed that the area with strong tidal currents shifted from the old river mouth(1976–1996) to the modern river mouth(1996–present). While the tidal current speeds decreased continually off the old river mouth, they increased off the modern river mouth. The Maximum Tidal Current Speed(MTCS) reached 1.4 m s-1, and the maximum current speed of 50-year return period reached 2.8 m s-1. Waves also changed greatly due to change in topography. The significant wave height(H1/3) of 50-year return period changed proportionately with the water depth, and the ratio of H1/3 to depth being 0.4–0.6. H1/3 of the 50-year return period in erosion zone increased continually with increasing water depth, and the rate of change varied between 0.06 and 0.07 m yr-1. Based on the results of this study, we infer that in the future, the modern river mouth will protrude gradually northward, while the erosion zone, comprising the old river mouth and area between the modern river mouth and the old river mouth(Intermediate region) will continue to erode. As the modern river mouth protrudes towards the sea, there will be a gradual increase in the current speed and decrease in wave height. Conversely, the old river mouth will retreat, with gradual decrease in current speed and increase in wave height. As more coastal constructions spring up around the Yellow River mouth in the future, we recommend that variation in hydrodynamics over time should be taken into consideration when designing such coastal constructions.     

Seasonal suspended particles distribution patterns in Western South Yellow Sea based on Acoustic Doppler Current Profiler observation

An Acoustic Doppler Current Profiler (ADCP) observation site was set up in the Western South Yellow Sea from 2012 to 2013 to study the local suspended particle matters (SPM) distribution pattern. The S...     

一种支持篡改定位的电子航海图零水印研究

本文针对电子航海图（ENC）使用过程中面临的数据安全问题,结合S-57标准下CRC校验和完整性认证需求,提出了一种顾及点位篡改定位特性的电子航海图零水印算法。该算法在分析ENC物标（要素）中以经纬度表示的离散点位坐标数据分布规律的基础上,构造离散点经纬度坐标数据校验码生成模型,结合离散点经纬度坐标数量对ENC单元格网进行二叉树分块处理,并分块解算基于离散点经纬度坐标校验码的二值序列,通过该二值序列与置乱加密后的水印图像进行异或操作构造零水印图像。算法中离散点的经纬度坐标校验码和格网分块技术的引入,在保证ENC数据精度和满足CRC校验的同时,具备点位篡改定位的特性。试验结果表明,该水印算法具有良好的稳健性、不可见性和一定的篡改定位精度,适用于电子航海图数据的版权保护。     

Numerical Study on Seasonal Transportation of the Suspended Sediments in the Modern Yellow River Mouth Effected by the Artificial Water and Sediment Regulation

Since 2002, an artificial water and sediment regulation(AWSR) has been carried out, which largely reduced water and sediment discharged from the Yellow River into the Bohai Sea. Although the sediment transport in the Yellow River Mouth(YRM) has been observed and modeled intensively since AWSR, but preferentially for the non-storm conditions. In this study, a three-dimensional current-wave-sediment coupled model, DHI-MIKE numerical model, was used to examine the seasonal suspended-sediment transport in the YRM after the AWSR. Results show that the seasonal distribution of suspended-sediments in the YRM is dominated by wind and wave rather than river input. The major transport pathway of suspended-sediments is from the western Laizhou Bay to the Bohai Strait during the winter monsoon, especially in storm events. In addition, about 66% of the river sediments deposit within 30 km of the YRM, which is smaller than previous estimations. It suggests that the YRM has been eroded in recent decades.