辽东山区人口地域分布研究

本文在分析了辽东山区土地资源特征和人口特征的基础上,从三个角度讨论了辽东山区的人口垂直分布特征,同时还详细分析了人口布局不合理对山区生态环境和经济的影响。并指出,适度移民、并村并点、整合山村及建设农村小集镇是调整山区人口布局,促进山区经济发展和生态环境恢复的有效途径。     

我国天山山区公路山地灾害及其防治

天山山区公路山地灾害主要出现于海拔>3000米的现代冰缘区,遭山地灾害威胁较严重的是独山子—库车公路和乌鲁木齐—库尔勒公路。较突出的山地灾害是雪崩、风吹雪、自然积雪、泥石流与石冰川,其次是倒石堆、热融滑塌和热融掏蚀。该区公路山地灾害防治应采取预防为主、防治结合的原则,此外应加强灾害预报。     

天山地区地震韵律的初步探讨

根据新疆及苏联天山地区的地震目录和古地震研究成果,将整个天山地区的地震韵律划分为地震世、地震亚世、地震期、地震幕、地震阶五级,探讨了各级韵律的特征。估计了我国天山地区未来地震活动趋势。     

吉尔吉斯北天山地区地震预报研究成果

吉尔吉斯北天山地震活动区建有两个综合预报实验场,15个高灵敏度地震台,7个地磁台,5个地电台,7个地球化学台,6个水动力台,2个自动地震台以及阿拉—阿尔恰地震地球物理观象台和Ⅰ级大地测量网。此外,这里还有苏联科学院高温研究所所属的地电、地磁和光测距台网。该区地震平静期为19—22±6年,地震活动具有周期性特征。强震震源沿北天山地震活动带迁移。文中还确定了与地震酝育相关的地震活动性、地球物理场、地球化学场、水文地球动力学等一系列参数,描述了一系列强震前兆效应;指出了强震发生时间的综合研究的重要意义。     

新疆古地磁研究及几个地质构造问题探讨

通过对塔里木、准噶尔、伊犁、昆仑山等地区古地磁研究获得了大量数据,结合磁性地层、古生物、沉积相等综合分析,对塔里木地块构造演化、新疆晚古生代构造分区划分、伊犁地块、天山板块等几个地质构造问题进行了探讨.     

Geochemistry of the Baishitouquan Amazonite—and Topaz—bearing Granite in the Mid—Tianshan Belt,Xinjiang,China

The Baishitouquan amazonite and topaz-bearing granite is one of the typical high-rubidium and high-fluorine granites in the eastern part of the Mid-Tianshan belt. This intrusion is in sharp contact with Mid-Proterozoic schists, gneisses and marbles, and is composed of four zones transitional from the bottom upwards: leucogranite, amazonite granite, topaz-bearing amazonite granite and topaz quartz albitite. The Baishitouquan granite contains highly ordered K-feldspar, Li-rich mica, Mn-rich garnet, α-quartz and low temperature zircon and is chemically high in Si, K, Na, Al, Li, Rb, Cs and F, and low in Ti, Fe, Ca, Mg, P, Co, Ni, Cr, V, Sr and Ba, with Na₂O<K₂O. Amazonite from the amazonite granite zone contains 1867 ppm Rb. The F contents of bulk rocks are 3040 and 4597 for the amazonite granite and topaz-bearing amazonite granite zones, respectively. These two zones have δ¹⁸O values of 8.97–9.85‰ (SMOW) and show flat REE distribution patterns with strong Eu depletion. K-Ar and Rb-Sr ages of this intrusion are 226. 6 Ma and 209. 6 Ma respectively, with an initial⁸⁷Sr/⁸⁶Sr ratio of 0.987±0.213. The Baishitouquan granite is the product of crystallization of a low temperature, and water, rubidium and fluorine-rich magma, which may have been derived from partial melting of muscovite-rich crustal rocks. Consolidation of this granite involved two contrasting and successive stages: melt crystallization and hydrothermal metasomatism and precipitation. Various geological features of this granite were formed during the transition from the magmatic to the hydrothermal stage.