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61.
东北地区冬半年积雪与气温对冻土的影响 总被引:3,自引:3,他引:0
利用东北地区121个气象站逐日冻土深度、积雪深度、平均气温、地表平均气温及降水量数据,分析了1964—2017年冬半年冻土的变化特征及气象要素对冻土的影响。结果表明:东北地区积雪深度、平均气温、地表平均气温与冻土深度相关系数较高,降水量相关性不大。20世纪60年代平均气温、地表平均气温及负积温最低,最大冻土深度为历年代最深;随着气候变暖,最大冻土深度以6.15 cm?(10a)-1的速率显著减小。冬半年平均最大冻土深度为123 cm,呈显著纬向分布,自辽东半岛向大兴安岭北部递增;随纬度和海拔高度的增加,平均气温和地表平均气温降低,负积温增加,且由北向南地气温差增大。最大冻土深度全区有90%以上的站点减少,减少速率以0.1~10 cm?(10a)-1为主。冻土持续时间随纬度升高而增加,月最大冻土深度和积雪深度最大值分别出现在3月和1月,最大冻土深度的增加要滞后于积雪深度的增加。由于积雪对地温的保温作用,积雪深度较浅时,冻土深度增加较明显,随着积雪深度的增加,冻土深度变化较小,积雪对冻土起到了保温的作用。对于高纬度地区站点,30 cm左右为积雪的保温界限值;对于沿海站点,积雪保温的界限值在5 cm左右;在相同地形下,冻土深度较浅区域积雪的保温值因海拔高度、气候特点而异。最大冻土深度对地表平均气温升温的响应更为显著,地表平均气温和平均气温每升高1 ℃,最大冻土深度将减小8.4 cm和10.6 cm,负积温每减少100 ℃?d,最大冻土深度减少4.9 cm。 相似文献
62.
许红 史国宁 廖宝林 陈刚 董树义 邱隆伟 李琦 罗进雄 申剑 曾晓起 王亚民 贺静 董刚 闫桂京 王宇喆 周星蕾 胡喜鹏 罗乔乔 陈竹 陶萌 纳琴 王晴 王英 沈江远 马骁 付和平 吴汉儒 马亚增 陈舒 《古地理学报》2021,23(4):771-788
珊瑚是地球上最古老的原住民,具有近6×108年的发育史,弱势群居、喜温和原地长成是珊瑚的基本特征。作者介绍了珊瑚-珊瑚礁的基本特征,综述了跨十年调查的研究区珍贵照片资料和相关认识,指出中国是全球主要的珊瑚-珊瑚礁国家,地位举足轻重;珊瑚-珊瑚礁作为地球生物多样性的代表,造岛、固礁、护鱼、防护岛岸流失,形成南海四大群岛280余座岛、礁、滩、沙,所构建庞大海洋生态系统是无与伦比的海洋生态资源和寸土寸金的南海海洋国土。提出划分南海珊瑚-珊瑚礁为中央区和周缘区2个分布区,阐述了南海中央区珊瑚-珊瑚礁的基本特征,系统汇集报道了间隔10年2个科考航次调查在浅水礁盘浮潜、至20 m水深浅潜-深潜和礁盘及开展岛、礁、滩、沙地质调查的发现,包括科学定名46种六放石珊瑚和6种八放软珊瑚等成果,同时,收集了西沙、中沙、东沙和南沙群岛海域的相关调查航次珊瑚照片;进一步阐述了单体环礁和复合环礁的特征及分布,并进行了初步对比,指出永乐环礁是南海唯一一个真正的切合达尔文模式的环礁,也是环礁发展到最高阶段的产物,构成现代海洋珊瑚-珊瑚礁形成演化研究最好的天然实验室。 相似文献
63.
To accurately evaluate ecological risks trigged by groundwater exploitation, it must be clarified the relationship between vegetation and groundwater. Based on remote sensing data sets MOD13Q1, groundwater table depth (WTD) and total dissolved solids (TDS), the relationship between groundwater and natural vegetation was analyzed statistically in the main plain areas of Qaidam Basin. The results indicate that natural vegetation is groundwater-dependent in areas where WTD is less than 5.5 m and TDS is less than 7.5 g/L. Aquatic vegetation, hygrophytic vegetation and hygrophytic saline-alkali tolerant vegetation are mainly distributed in areas with WTD <1.1 m. Salt-tolerant and mesophytic vegetation mainly occur in areas with WTD of 1.4-3.5 m, while the xerophytic vegetation isprimarily present in areas where WTD ranges from 1.4 m to 5.5 m. Natural vegetation does not necessarily depend on groundwater in areas with WTD >5.5 m. For natural vegetation, the most suitable water TDS is less than 1.5 g/L, the moderately suitable TDS is 1.5-5.0 g/L, the basically suitable TDS is 5.0-7.5 g/L, and the unsuitable TDS is more than 7.5 g/L. 相似文献
64.
65.
A.M Celál Şengör Si̇lva Büyükaşikoğlu Nezi̇hi̇ Canitez 《Journal of Structural Geology》1983,5(2):211-216
Data for the post-Serravallian, ‘neotectonic’ evolution of the Pontides in northern Turkey indicate predominant ENE-WSW shortening with complementary NNW-SSE extension. We present a new fault plane solution for the Bartin earthquake (3 September 1968) and compare its mechanism with the movement picture of other neotectonic faults in the Pontides and northern Greece together with that of the Thessaloniki earthquake (20 May 1978). The general strain pattern exhibited by these structures agrees remarkably well with that inferred from early Tortonian-early Pleistocene structures reported from within the North Anatolian fault zone, which have been interpreted as indicating a possible reversal of the sense of movement along the North Anatolian transform fault. Here, we argue that such ‘incompatible’ structures may be related to the overall E-W shortening of Anatolia and the southern parts of the Black Sea resulting from the sideways continental escape from around the African and the Arabian promontories, rather than to hypothetical reversal of motion along the North Anatolian fault, for which there is no evidence other than the above-mentioned ‘incompatible’ structures. This new model also has important implications for seismicity and earthquake risk in regions contained within the southern part of the Black Sea plate. 相似文献
66.
青藏高原的剥蚀与构造抬升* 总被引:8,自引:5,他引:8
利用宇宙成因核素10 Be和26 Al对西昆仑和可可西里北部地表基岩的剥蚀速率进行了测定,得到的结果是:西昆仑的平均剥蚀速率为12m/Ma, 可可西里北部的平均剥蚀速率为15m/Ma。裂变径迹和宇宙成因核素这两种手段所得到的平均剥蚀速率的时间尺度是不同的,前者得到的是几个至数十百万年的平均剥蚀速率,而后者得到的是十几至几十万年的平均剥蚀速率。比较通过这两种手段得到的青藏高原北部和中部的平均剥蚀速率可以发现其平均剥蚀速率从20Ma以来的100m/Ma以上减少到了最近几十万年以来的10m/Ma,我们认为这一剥蚀速率下降的趋势反映了青藏高原从中新世到第四纪晚期构造活动的减弱,据此推断青藏高原北部和中部的隆升应该主要发生在第四纪晚期之前,而不是在最近的几十万年。 相似文献
67.
通过对大港滩海区埕北断阶带层序地层的研究,将研究区古近系划分为3个三级层序,总结了5种识别层序界面的方法:①地震识别法;②钻井识别法;③测井识别法;④古生物组合识别法;⑤地球化学识别法。在研究区,方法①表现为区域性的上超和削截;方法②表现为岩性和泥岩颜色的突变;方法③表现为各种曲线和地层倾角的突变;方法④表现为古生物组合类型的变化;方法⑤表现为Fe^2+/Mn^2+值由下向上由逐渐增大,转为突然变小。其中方法①、③、④是层序界面的主要识别标志,方法②可作为参考标志,而方法⑤的应用效果较差。 相似文献
68.
69.
Summary Monthly rainfall totals at 7 stations across Turkey and sea level pressure (SLP) in 16 grid points in the region delimited
by the 20° E and 50° E longitudes and by the 30° N and 45° N latitudes were analysed. Data were available for a period longer
than sixty years. The standard deviations of SLP at each grid point for each month, were calculated and mapped. For each station,
months were defined as dry or wet according to their z scores: ≤ −1.0 or ≥ 1.0 respectively. Maps showing the SLP z scores of the corresponding dry or wet months for each station were prepared. The maps, enable to distinguish between SLP patterns associated with dry or wet conditions.
Furthermore, correlations between monthly rainfall in each of the stations and SLP at each grid point were performed. The
correlation coefficients were mapped.
(a) The variability of the SLP decreases from the Balkans towards the Arabian Peninsula and is much larger in winter as compared
with summer. (b) Relationship between rainfall in Turkey and the regional SLP is large in winter and non existing in summer.
(c) Pressure patterns associated with dry conditions, show usually positive SLP departures, whereas, pressure patterns associated with wet conditions show usually negative SLP departures. (d) There is a great resemblance between pressure patterns associated with
wet conditions and correlation maps of the same months.
Received September 4, 2000 Revised January 15, 2001 相似文献
70.
Northwestern Anatolia contains three main tectonic units: (a) the Pontide Zone in the north which consists mainly of the Gstanbul-Zonguldak Unit in the west and the BallLda<-Küre Unit in the east; (b) the Sakarya Zone (or Continent) in the south, which is juxtaposed against the Pontide Zone due to the closure of Paleo-Tethys prior to Late Jurassic time; and (c) the Armutlu-OvacLk Zone which appears to represent a tectonic mixture of both zones. These three major tectonic zones are presently bounded by the two branches of the North Anatolian Transform Fault. The two tectonic contacts follow older tectonic lineaments (the Western Pontide Fault) which formed during the development of the Armutlu-OvacLk Zone. Since the earliest Cretaceous, an overall extensional regime dominated the region. A transpressional tectonic regime of Coniacian/Santonian to Campanian age caused the welding of the Gstanbul-Zonguldak Unit to the Sakarya Zone by an oblique collision. In the Late Campanian, a transtensional tectonic regime developed, forming a new basin within the amalgamated tectonic mosaic. The different tectonic regimes in the region were caused by activity of the Western Pontide Fault. Most of the ophiolites within the Armutlu-OvacLk Zone belong to the Paleo-Tethyan and/or pre-Ordovician ophiolitic core of the Gstanbul-Zonguldak Unit. The Late Cretaceous ophiolites in the eastern parts of the Armutlu-OvacLk Zone were transported from Neo-Tethyan ophiolites farther east by left-lateral strike-slip faults along the Western Pontide Fault. There is insufficient evidence to indicate the presence of an ocean (Intra-Pontide Ocean) between the Gstanbul-Zonguldak Unit and the Sakarya Zone during Late Cretaceous time. 相似文献