Neogene evolution of the NW European Atlantic margin: Results from the STRATAGEM project   总被引：1，自引：0，他引：1  

Martyn S. Stoker  Patrick M. Shannon 《Marine and Petroleum Geology》2005,22(9-10):965

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Cambridge deep Ocean geophone     

Jeremy Duschenes  Chris Potts  Martyn Rayner 《Marine Geophysical Researches》1985,7(4):455-466

We describe recent mechanical andeelectronic modifications to the Cambridge Ocean Bottom Hydrophone system, enabling it to record in addition three geophone channels from a deployed, disposable geophone package. Examples of data from seismic refraction experiments show good correspondence between records of ground motion detected by the hydrophone and the vertical geophone. Seismic signals are undistorted by noise from instrument related sources. Clear examples of P to S conversions just below the receiver are observed. Improved recording conditions are achieved by deploying the geophones in a small pressure vessel as far away as possible from the main instrument package.  相似文献   

Partial melt or aqueous fluid in the mid-crust of Southern Tibet? Constraints from INDEPTH magnetotelluric data   总被引：13，自引：0，他引：13  

Shenghui Li  Martyn J. Unsworth  John R. Booker  Wenbo Wei  Handong Tan  Alan G. Jones 《Geophysical Journal International》2003,153(2):289-304

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Diagnosing snow accumulation errors in a rain‐snow transitional environment with snow board observations          下载免费PDF全文

Nicholas E. Wayand  Martyn P. Clark  Jessica D. Lundquist 《水文研究》2017,31(2):349-363

Diagnosing the source of errors in snow models requires intensive observations, a flexible model framework to test competing hypotheses, and a methodology to systematically test the dominant snow processes. We present a novel process‐based approach to diagnose model errors through an example that focuses on snow accumulation processes (precipitation partitioning, new snow density, and snow compaction). Twelve years of meteorological and snow board measurements were used to identify the main source of model error on each snow accumulation day. Results show that modeled values of new snow density were outside observational uncertainties in 52% of days available for evaluation, while precipitation partitioning and compaction were in error 45% and 16% of the time, respectively. Precipitation partitioning errors mattered more for total winter accumulation during the anomalously warm winter of 2014–2015, when a higher fraction of precipitation fell within the temperature range where partition methods had the largest error. These results demonstrate how isolating individual model processes can identify the primary source(s) of model error, which helps prioritize future research.  相似文献   

Spatial variability of hydrological processes and model structure diagnostics in a 50 km2 catchment          下载免费PDF全文

Hilary McMillan  Myriam Gueguen  Elisabeth Grimon  Ross Woods  Martyn Clark  David E. Rupp 《水文研究》2014,28(18):4896-4913

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Magnetotelluric evidence for asymmetric simple shear extension and lithospheric thinning in South China     

Shan Xu  Martyn J. Unsworth  Xiangyun Hu  Walter D. Mooney 《《地质学报》英文版》2018,92(Z1):92-93

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Lower Pleistocene deltaic and marine sediments in boreholes from the central North Sea     

Martyn S. Stoker  Alistair J. A. Bent 《第四纪科学杂志》1987,2(2):87-96

Lower Pleistocene sediments recovered in boreholes from the Aberdeen Ground Formation in the central North Sea indicate that the unit was deposited in a delta front to prodelta/shallow, open shelf marine setting. Possible estuarine and clastic nearshore marine deposits have been identified on the western margin of the basin. The delta front sediments consist of interbedded, structureless to laminated sands and muds with organic debris, ferruginous nodules and common soft sediment deformation structures. Sporadic rippled and graded beds, basal scours to beds and starved ripples suggest periodic wave–current reworking. Prodelta/shelf marine sediments are predominantly argillaceous with only occasional thin sand beds and rare phosphatic bands. One exceptionally thick sand body or submarine channel-fill although this remains uncertain. The estuarine/clastic nearshore marine sediments include coarse channel-lag deposits and rippled and laminated subtidal sands. A rich microfossil assemblage recovered from the prodelta/shelf marine sequence indicates that deposition occurred under fluctuating climatic conditions.  相似文献   

藏北高原地壳及上地幔导电性结构——超宽频带大地电磁测深研究结果   总被引：13，自引：14，他引：13       下载免费PDF全文

魏文博  金胜  叶高峰  邓明  谭捍东  Martyn Unsworth  Alan G.Jones  John Booker  Shenghui Li 《地球物理学报》2006,49(4):1215-1225

为了研究西藏中、北部壳、幔导电性结构，讨论高原中、北部岩石圈热状态，1998年和1999年（INDEPTH（Ⅲ） MT）在西藏中、北部完成了德庆—龙尾错（500线）和那曲—格尔木（600线）超宽频带大地电磁深探测剖面的研究.研究结果表明，西藏中、北部以昆仑山断裂为界，其南北壳、幔电性结构有很大差异.昆仑山断裂以北地壳和上地幔为高阻区.而昆仑山以南，地壳和上地幔的导电性有明显的分层结构：地壳上部以不连续的高阻体为主，夹有局部低阻异常体，沿南北方向上地壳的电性结构复杂，具有不连续、分块的特点；但中、下地壳为大范围的高导异常区，区内发育有大规模、不相连续、产状各异的高导体，其电阻率均小于4Ωm；在班公—怒江和金沙江缝合带之下，壳内高导体都具有向上地幔延伸的趋势，存在连通壳、幔的低阻通道.根据西藏高原中、北部壳、幔电性结构的研究推断：如同藏南一样，这里也普遍存在部分熔融体和热流体，它们的成因主要与班公—怒江和金沙江缝合带的壳-幔热交换、热活动有关，这是两期形成的壳-幔热交换通道.其中，班公—怒江缝合带的壳-幔热交换通道形成时间比金沙江缝合带早.因此，研究区壳、幔的热活动是从南边和西边开始，向北、向东扩展，导致现今西藏中、北部地壳和上地幔的热流分布由西向东、由南向北增大.  相似文献   

Research of the Conductive Structure of Crust and the Upper Mantle beneath the South-Central Tibetan Plateau     

叶高峰金胜  魏文博Martyn Unsworth 《中国地质大学学报(英文版)》2007,18(4):334-343

With the super-wide band magnetotelluric sounding data of the Jilong (吉隆)-Cuoqin (措勤) profile (named line 800) which was completed in 2001 and the Dingri (定日)-Cuomai (措迈) profile (named line 900) which was completed in 2004,we obtained the strike direction of each MT station by strike analysis,then traced profiles that were perpendicular to the main strike direction,and finally obtained the resistivity model of each profile by nonlinear conjugate gradients (NLCG) inversion. With these two models,we described the resistivity structure features of the crust and the upper mantle of the center-southern Tibetan plateau and its relationship with Yalung Tsangpo suture: the upper crust of the research area is a resistive layer with resistivity value range of 200-3 000 ?·m. The depth of its bottom surface is about 15-20 km generally,but the bottom surface of resistive layer is deeper in the middle of these two profiles. At line 900,it is about 30 km deep,and even at line 800,it is about 38 km deep. There is a gradient belt of resistivity at the depth of 15-45 km,and a conductive layer is beneath it with resistivity even less than 5 ?·m. This conductive layer is composed of individual conductive bodies,and at the south of the Yalung Tsangpo suture,the conductive bodies are smaller with thickness about 10 km and lean to the north slightly. However,at the north of the Yalung Tsangpo suture,the conductive bodies are larger with thickness about 30 km and also lean to the north slightly. Relatively,the conductive bodies of line 900 are thinner than those of line 800,and the depth of the bottom surface of line 900 is also shallower. At last,after analyzing the effect factors to the resistivity of rocks,it was concluded that the very conductive layer was caused by partial melt or connective water in rocks. It suggests that the middle and lower crust of the center-southern Tibetan plateau is very thick,hot,flabby,and waxy.  相似文献   

‘Reconstructing middle to late Holocene sea‐level change: A methodological review with particular reference to “A new Holocene sea‐level curve for the southern North Sea” presented by K.‐E. Behre’: Reply to comments     

Cecile Baeteman  Martyn Waller  Patrick Kiden 《Boreas: An International Journal of Quaternary Research》2012,41(2):315-318

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