岬间海湾滨面带波浪结构和外观统计特征

对中等波能条件下收集的粤东两个岬间海湾滨面带４个站点的波浪数据作了滨面带波面、波包和 长重力波的基本特征的分析，得到如下主要结果：（１）滨面带波谱由多峰频构成，从海向岸波高增大， 波周期减小，谱宽度加大，谱尖度减小；（２）入射波群性较强，表征入射波群性的相对均方根群高与谱 宽度无关；（３）长波振幅与波浪能量增大，其形成主要与组成波间的非线性相互作用有关。

加拿大Beaufort海沙质极冷滨面风暴成因混合流的海底响应

加拿大Ｂｅａｕｆｏｒｔ海沙质极冷滨面风暴成因混合流的海底响应Ａ．Ｈｅｑｕｅｔｔｅ等滨面是指波浪未及破碎的浅滩带，为内陆架与浪击带之间的重要过渡区。由于演面水深较浅，水体受风及波浪振动造成的垂向混合作用影响，结果波浪振动流与常向流相互作用形成较强的底床...

陆丰13-2油田滨岸相储层沉积微相研究

陆丰13-2油田2370层是一个反韵律块状砂岩油藏,根据沉积、测井及储层物性特征,可将2370层临滨亚相进一步划分为下滨面砂、沿岸砂坝和上滨面砂,其中以沿岸砂坝中的内砂坝储层物性最好,非均质性最弱,产能最高。沉积特征研究表明,2370层沉积层序具有二元结构,即下临滨为进积型泥质低能海岸沉积层序,中上临滨为进积型砂质高能海岸沉积层序,二者沉积特征和储层物性相差较大。

川西龙门山前上三叠统小塘子组沉积环境、构造含意与含气远景

在实测绵竹汉旺和广元何家湾小塘子组(T_3t)地层剖面的基础上,详细研究了它们的沉积相。何家湾T_3t属浅水环境:滨面砂坝、陆架泥、潮坪和浪控三角洲。汉旺T_3t则以显著的深水相为特征:滨面砂坝,海湾泥、中缓坡水道与滑塌席、三角洲前缘沉积。对汉旺剖面所含黄铁矿结核作了初步研究。T_3t总的说符合富砂泥缓坡的沉积模式。指出汉旺剖面中部的半深水泥岩标志着龙门山活跃的逆冲构造运动,而以上的HST以至须二段下部厚砂体才是构造活动平静期的产物。认为小塘子组底部滨面砂体极具天然气勘探远景。

香菇多糖联合GP方案治疗晚期非小细胞肺癌25例

目的评价香菇多糖联合吉西他滨和顺铂(GP方案)治疗晚期非小细胞肺癌(NSCLC)的近期疗效及对患者生活质量的影响。方法将51例ⅢB和Ⅳ期NSCLC患者随机分为治疗组25例和对照组26例,均给予吉西他滨1 000 mg·(m2)-1,第1,8天静脉滴注;顺铂25 mg·(m2)-1,第2～4天静脉滴注。21 d为1个周期,两个周期后评价疗效。治疗组同时给予香菇多糖2 mg+5%葡萄糖注射液或0.9%氯化钠注射液250 mL,第1,4天静脉滴注。两组化疗前均给予5-羟色胺受体拮抗药预防性止吐,并常规给予水化利尿处理。结果两组QLQ-C30生活质量评分均较治疗前升高,治疗组整体生活质量评分显著高于对照组,乏力较对照组显著改善(P<0.05);两组QLQ-LC-13肺癌相关症状(咳嗽、呼吸困难、胸痛)评分较治疗前均下降;治疗组细胞免疫功能较治疗前无变化,对照组免疫功能下降,两组治疗后比较差异有统计学意义(P<0.05);对照组白细胞减少多于治疗组。结论香菇多糖联合GP方案化疗治疗晚期非小细胞肺癌可有效控制NSCLC进展,减轻化疗不良反应,预防患者细胞免疫功能损伤,明显改善患者的生活质量。

怀俄明州西南Moxa穹隆的沉积、成岩和构造对Frontier组储层特征的控制作用

怀俄明州西南的Moxa穹隆的Frontier组地层提供了在沉积、成岩和构造之间的相互作用影响储层性质和动态的极好例证。在白垩纪,前陆盆地西部的塞维尔造山带发生上冲隆起和地壳超载。在Frontier组沉积期间,上冲岩片为Moxa穹隆区提供了大量的沉积物。这些沉积物堆集在浪控三角洲、海滨平原、海岸平原和下切河谷填积相的沉积环境中。塞维尔造山带的构造活动致使沿Moxa穹隆的矩形基底断块发生了周期性的差异运动。这些运动致使在断块边界形成了线性裂缝形态。此外,基底断块的反复运动影响了Frontier组的古构造、成岩流体的运移通道和沉积物扩散形式。 Frontier组沉积物的沉积相控制了Moxa穹隆Frontier组储集层原生孔隙度和渗透率的变化趋势。沿基底断块边界软弱岩层的反复差异运动形成的沉积后的裂缝提高了Frontier组储集层的次生渗透率和动态特征。Frontier组的沉积相和沉积后的断裂作用影响了成岩作用的趋势,而后者又影响了沿Moxa穹隆的Frontier组储集层的次生孔隙度和渗透率的特征。正是这种沉积、构造和成岩作用之间复杂的相互作用控制了Moxa穹隆的Frontier组的储层特征。

上海“北外滩”将成为投资热点

近年来,上海“北外滩”地区的开发建设逐渐引起人们的关注。上海虹口区“北外滩”规划办公室主任蒋诚赞认为,此地有望成为投资热点。

Research on Purification Effect of Jian Lake Zizania latifolia Wetland Lakefront Zone in Northwest of Yunnan Plateau on Nitrogen and Phosphorus of Agricultural Non-point Source

As the main external pollution source of lake,nitrogen and phosphorus from agricultural non-point source make a great contribution to the lake eutrophication pollution.Wetland lakefront zone which plays a key role in externally agricultural non-point source pollution is considered as the biggest barrier for controlling external pollution.In this research,the Jian lake plateau Zizania latifolia wetland lakefront zone was selected for agricultural non-point source pollutions control with the systematic field research,and the lakefront zone was approved to have an effective purification effect on nitrogen and phosphorus from Jinlong River; the theoretical mechanism of lakefront zone removing nutrient was also investigated.Z.latifolia wetland lakefront zone could remove nitrogen and phosphorus from Jinlong River and the removal ratio can reach 55.8-62.52% and 59.47-69.81% respectively.So,we can indicate that the Jian Lake plateau Z.latifolia wetland lakefront zone had a good effect on controlling agricultural non-point source pollution and protecting the environment.

Phosphorus Behavior at Sediment-Water Interface in Coastal Wetland

[Objective] The aim was to explore the role of coastal wetlands in phosphorus fixation in the Yellow River Delta.[Method] The research analyzed phosphorus behavior at sediment-water interface by static water column test. [Result] The research concluded that phosphorus concentration was in the range of 0.051-0.322 mg/L in overlying water, and phosphorus was effectively removed by degradation and adsorption. The static water column test has demonstrated that phosphorus concentration of coastal wetlands plays the role of accumulation when phosphorus concentration is lower than 7 mg/L in overlying water of coastal wetlands. It is notable that substrates of overlying water all perform well in adsorption, and the adsorption reaches saturation if the concentration goes up to 10 mg/L. [Conclusion] Coastal wetlands would significantly adsorb and degrade phosphorus in overlying water, controlling phosphorus within a lower range.