全文获取类型
收费全文 | 33844篇 |
免费 | 507篇 |
国内免费 | 373篇 |
专业分类
测绘学 | 723篇 |
大气科学 | 2209篇 |
地球物理 | 6180篇 |
地质学 | 12773篇 |
海洋学 | 3360篇 |
天文学 | 7689篇 |
综合类 | 79篇 |
自然地理 | 1711篇 |
出版年
2022年 | 307篇 |
2021年 | 504篇 |
2020年 | 563篇 |
2019年 | 622篇 |
2018年 | 1163篇 |
2017年 | 1116篇 |
2016年 | 1244篇 |
2015年 | 655篇 |
2014年 | 1144篇 |
2013年 | 1931篇 |
2012年 | 1291篇 |
2011年 | 1652篇 |
2010年 | 1458篇 |
2009年 | 1816篇 |
2008年 | 1510篇 |
2007年 | 1566篇 |
2006年 | 1466篇 |
2005年 | 904篇 |
2004年 | 867篇 |
2003年 | 818篇 |
2002年 | 842篇 |
2001年 | 713篇 |
2000年 | 663篇 |
1999年 | 554篇 |
1998年 | 565篇 |
1997年 | 508篇 |
1996年 | 464篇 |
1995年 | 412篇 |
1994年 | 435篇 |
1993年 | 351篇 |
1992年 | 346篇 |
1991年 | 352篇 |
1990年 | 372篇 |
1989年 | 268篇 |
1988年 | 267篇 |
1987年 | 333篇 |
1986年 | 253篇 |
1985年 | 373篇 |
1984年 | 353篇 |
1983年 | 314篇 |
1982年 | 323篇 |
1981年 | 268篇 |
1980年 | 303篇 |
1979年 | 241篇 |
1978年 | 273篇 |
1977年 | 212篇 |
1976年 | 213篇 |
1975年 | 206篇 |
1974年 | 206篇 |
1973年 | 200篇 |
排序方式: 共有10000条查询结果,搜索用时 10 毫秒
991.
A. D. Nozhkin I. I. Likhanov V. V. Reverdatto T. B. Bayanova S. V. Zinoviev P. S. Kozlov N. V. Popov N. V. Dmitrieva 《Doklady Earth Sciences》2017,474(2):674-679
The Late Vendian (540–550 Ma) U–Pb zircon age of postcollisional granitoids in the Osinovka Massif was obtained for the first time. The Osinovka Massif is located in rocks of the island-arc complex of the Isakovka Terrane, in the northwestern part of the Sayany–Yenisei accretion belt. These events stand for the final stage of the Neoproterozoic history of the Yenisei Ridge, related to the completing accretion of the oceanic crust fragments and the beginning of the Caledonian orogenesis. The petrogeochemical composition and the Sm–Nd isotopic characteristics support the fact that the granitoid melt originated from a highly differentiated continental crust of the southwestern margin of the Siberian Craton. Hence, the granite-bearing Late Riphean island-arc complexes were thrust over the craton margin at a distance considerably exceeding the dimensions of the Osinovka Massif. 相似文献
992.
993.
A.-M. Ertel A. Lupo N. Scheifhacken T. Bodnarchuk O. Manturova T. U. Berendonk T. Petzoldt 《Environmental Earth Sciences》2012,65(5):1459-1473
A pronounced pollution of surface water bodies in the Western Bug River Basin, Ukraine, has been caused by outdated or overloaded
wastewater treatment plants, agriculture, industry and coal mining. These pressures have led to a generally poor state of
both chemical and microbiological variables creating health risks of various kinds. The state of surface water quality for
the Western Bug and five main tributaries was assessed by measuring physical, chemical and microbiological indicators during
field campaigns in autumn 2009 and spring 2010. Longitudinal profiles were sampled to identify major sources of pollution
and to reveal dominant processes of matter turnover. In addition, the occurrence of antibiotic resistant strains in isolates
from stations along the Bug River was investigated. Results clearly underpin the negative impact of the Poltva River as a
major source of pollution for the Bug River and further outline an elevated potential health risk from pathogenic bacteria
originating from this source. Despite these devastating impacts, a high elimination potential of the Bug River with respect
to primary organic loads as well as elimination of pathogenic bacteria was observed particularly at Dobrotvir Reservoir. Further
downstream, pollution is kept high because of untreated waste effluents and phytoplankton mass developments due to high phosphorus
concentrations. 相似文献
994.
N. S. Zhatnuev 《Doklady Earth Sciences》2010,430(2):176-180
This study attempts to substantiate a model of magma ascent from deep-seated sources driven by the density difference between magmas and wall rocks in a plastic solid medium via hydraulic fracturing (magma-driven fracturing). The difference between magma and wall rock densities causes overpressure development in the head of a magma column. With increasing height of the column or decreasing magma density, the overpressure can build significantly, which is valid for the case of continuous magma conduit from a deepseated source. The depth of mantle chambers, their vertical extent, and magma densities seem to be the key factors in the formation of volcanoes and intracrustal intrusions. Intermittent (or peripheral) magma chambers under volcanoes and crustal-mantle intrusive bodies may be formed at strength barriers, in the zone of elastoplastic transition and at the mantle-crust boundary. 相似文献
995.
Gold ore districts in the Siberian (North Asian) craton and bordering terranes have been studied. Studies showed the long duration of gold concentration processes (Early Cambrian to Late Mesozoic and Cenozoic) and the influence of structural geological, magmatic, and metallogenic factors on the formation of ore districts. The largest Late Mesozoic (J–K) accumulations of gold deposits in southeastern Russia were discovered in the Aldan–Stanovoi Shield and at the northern margin of the Argun superterrane in the Aldan (Yakutia), Balei (Transbaikalia), and Gonzha (Upper Amur area) ore–placer districts.The geological and geophysical positions of these three districts have been compared. All of them are situated in zones of influence of variously trending long-lived deep faults, bordered by large Precambrian uplifts, and spatially (paragenetically) related to local magma chamber domes of Late Mesozoic (J–K) intrusive, subvolcanic, and extrusive–effusive bodies, dikes, and terrigenous pyroclastic blankets. The areas of Jurassic–Cretaceous volcanoplutonic rocks are related to the influence of the East Asian sublithospheric “superplume.”All this confirms the important ore-controlling role of large long-lived deep faults (in the form of global and regional gravity gradient zones) in the distribution of highly productive precious-metal ore–magmatic systems. This suggests that the junctions between gravity gradient zones of different trends and ranks are important to the identification of gold prospects in metallogenic prediction studies and small-scale prospecting. The Archean–Proterozoic age and the great occurrence depth of the tectonic zones suggest that extensive long-lived mobile zones (before the post-Cambrian breakup of the Siberian craton) significantly affected further evolution of the orogenic belts bordering the craton and their metallogeny, including the distribution of precious- metal deposits. 相似文献
996.
I. V. Pekov N. V. Zubkova N. V. Chukanov A. E. Zadov V. G. Grishin D. Yu. Pushcharovsky 《Geology of Ore Deposits》2010,52(7):584-590
A new mineral, yegorovite, has been identified in the late hydrothermal, low-temperature assemblage of the Palitra hyperalkaline pegmatite at Mt. Kedykverpakhk, Lovozero alkaline pluton, Kola Peninsula, Russia. The mineral is intimately associated with revdite and megacyclite, earlier natrosilite, microcline, and villiaumite. Yegorovite occurs as coarse, usually split prismatic (up to 0.05 × 0.15 × 1 mm) or lamellar (up to 0.05 × 0.7 × 0.8 mm) crystals. Polysynthetic twins and parallel intergrowths are typical. Mineral individuals are combined in bunches or chaotic groups (up to 2 mm); radial-lamellar clusters are less frequent. Yegorovite is colorless, transparent with vitreous luster. Cleavage is perfect parallel to (010) and (001). Fracture is splintery; crystals are readily split into acicular fragments. The Mohs hardness is ~2. Density is 1.90(2) g/cm3 (meas) and 1.92 g/cm3 (calc). Yegorovite is biaxial (?), with α = 1.474(2), β = 1.479(2), and γ = 1.482(2), 2V meas > 70°, 2V calc = 75°. The optical orientation is X ∧ a ~ 15°, Y = c, Z = b. The IR spectrum is given. The chemical composition determined using an electron microprobe (H2O determined from total deficiency) is (wt %): 23.28 Na2O, 45.45 SiO2, 31.27 H2Ocalc; the total is 100.00. The empirical formula is Na3.98Si4.01O8.02(OH)3.98 · 7.205H2O. The idealized formula is Na4[Si4O8(OH)4] · 7H2O. Yegorovite is monoclinic, space group P21/c. The unit-cell dimensions are a = 9.874, b= 12.398, c = 14.897 Å, β = 104.68°, V = 1764.3 Å3, Z = 4. The strongest reflections in the X-ray powder pattern (d, Å (I, %)([hkl]) are 7.21(70)[002], 6.21(72)[012, 020], 4.696(44)[022], 4.003(49)[211], 3.734(46)[(bar 2) 13], 3.116(100)[024, 040], 2.463(38)[(bar 4)02, (bar 2)43]. The crystal structure was studied by single-crystal method, R hkl = 0.0745. Yegorovite is a representative of a new structural type. Its structure consists of single chains of Si tetrahedrons [Si4O8(OH)4]∞ and sixfold polyhedrons of two types: [NaO(OH)2(H2O)3] and [NaO(OH)(H2O)4] centered by Na. The mineral was named in memory of Yu. K. Yegorov-Tismenko (1938–2007), outstanding Russian crystallographer and crystallochemist. The type material of yegorovite has been deposited at the Fersman Mineralogical Museum of Russian Academy of Sciences, Moscow. 相似文献
997.
In 2008, during cruise 24 of the R/V Akademik Vavilov, much of our research work was focused on the central segment (Jaseur and Davis seamounts, Dogaressa Bank) of the Vitoria-Trindade seamount chain (west of the Brazil basin) extending along 20.5° S. Work was conducted to survey the upper part of the sedimentary cover and to perform subbottom profiling. The samples dredged on the seamount slopes are represented by volcanites and Fe-Mn crusts. 相似文献
998.
999.
1000.