甘肃临洮晚更新世黄土环境变迁

曾方明; 向树元; 路玉林; 马新民; 路晶芳

甘肃临洮晚更新世黄土环境变迁

1.
中国地质大学地球科学学院, 湖北武汉 430074
2.
中国科学院地质与地球物理研究所, 北京 100029
3.
中国石油勘探开发研究院西北分院, 甘肃兰州 730020

基金项目:

中国地质调查局综合研究项目 1212010610103

中国地质调查局区调项目 200413000007

详细信息

作者简介:
曾方明(1982—), 男, 硕士研究生, 主要从事第四纪地质研究.E-mail：zengfangming2007@163.com

中图分类号: P534
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出版历程
- 收稿日期: 2007-06-16
- 刊出日期: 2007-09-25

Environmental Evolution of Late Pleistocene Loess Deposits at Lintao County, Gansu Province

1.
Faculty of Earth Sciences, China University of Geosciences, Wuhan 430074, China
2.
Institute of Geology and Geophysics, Chinese Academic of Sciences, Beijing 100029, China
3.
North west Branch of the Research Institute of Petroleum Exploration and Development, PetroChina, Lanzhou 730020, China

摘要

摘要: 对甘肃临洮县塔湾乡晚更新世黄土-古土壤序列的粒度、磁化率两个环境代用指标进行综合分析, 可划分出以下7个气候阶段: (1) 距底18.5m (92.478.8ka), 平均粒径24.42μm, 平均磁化率716.8×10^-6SI, 年均温度7.8℃, 年均降水量500mm, 气候温暖较湿; (2) 距底8.514.8m (78.865.3ka), 平均粒径26.83μm, 平均磁化率为442.3×10^-6SI, 年均温度5.2℃, 年均降水量370mm, 气候温干; (3) 距底14.820.3m (65.357.3ka), 平均粒径25.94μm, 平均磁化率320.7×10^-6SI, 年均温度3.5℃, 年均降水量280mm, 气候温干偏凉; (4) 距底20.324.9m (57.347.7ka), 平均粒径25.23μm, 平均磁化率516.4×10^-6SI, 年均温度6.0℃, 年均降水量410mm, 气候温干偏湿; (5) 距底24.929.4m (47.740.9ka), 平均粒径25.46μm, 平均磁化率299.4×10^-6SI, 年均温度在3.1℃, 年均降水量270mm, 气候温干偏凉; (6) 距底29.434.2m (40.932.4ka), 平均粒径21.46μm, 平均磁化率405.5×10^-6SI, 年均温度4.7℃, 年均降水量350mm, 气候温干偏湿; (7) 距底34.239m (32.4ka以后), 平均粒径188.89μm, 平均磁化率381.1×10^-6SI, 年均温度4.4℃, 年均降水量330mm, 气候温干.这些环境变迁阶段与区域环境变迁具有较好的可对比性, 其中Ⅰ阶段相当于MIS5温暖期; Ⅱ阶段和Ⅲ阶段相当于MIS4降温期; Ⅳ阶段、Ⅴ阶段和Ⅵ阶段相当于MIS3的气候温暖期; Ⅶ阶段相当于MIS2降温期.但与邻区兰州九洲台和若尔盖RM孔相比, 同时期临夏地区气候明显偏温偏湿.
- 甘肃临洮 /
- 晚更新世 /
- 黄土 /
- 环境变迁
Abstract: According to the comprehensive analysis of granularity and magnetic susceptibility of late Pleistocene loess-paleosol sequence at Tawan, Lintao County, Gansu Province, the climate change in this area can be divided into seven phases. (1) 1-8.5 m above the bottom (92.4-78.8 kaBP) : the average value of particle diameter and magnetic susceptibility was 24.42 μm and 716.8×10^-6 SI, and the annual average temperature and precipitation reached to 7.8 ℃ and 500 mm, being the highest of the seven phases, indicating warm and wet climate. (2) 8.5-14.8 m above the bottom (78.8-65.3 kaBP) : the average value of particle diameter and magnetic susceptibility was 26.83 μm and 442.3×10^-6 SI, and the annual average of temperature and precipitation was about 5.2 ℃ and 370 mm. The climate was tepid and dry. (3) 14.8-20.3 m above the bottom (65.3-57.3 kaBP) : the mean of particle diameter and magnetic susceptibility was 25.94 μm and 320.7×10^-6 SI, and the annual average temperature and precipitation was about 3.5 ℃ and 280 mm. The climate changed to be mild-dry and slightly cool. (4) 20.3-24.9 m above the bottom (57.3-47.7 kaBP) : the average value of particle diameter and magnetic susceptibility was 25.23 μm and 516.4×10^-6SI, and the annual average temperature and precipitation reached 6.0 ℃and 410 mm. It was mild-dry and slightly wet. (5) 24.9-29.4 m above the bottom (47.7-40.9 kaBP) : the mean of particle diameter and susceptibility was 25.46 μm and 299.4×10^-6 SI, and the annual average temperature and precipitation was 3.1 ℃ and 270 mm. The climate was mild-dry and slightly cool. (6) 29.4-34.2 m above the bottom (40.9-32.4 kaBP) : the average value of particle diameter and susceptibility was 21.46 μm and 405.5×10^-6 SI, and the annual average temperature and precipitation was about 4.7 ℃ and 350 mm. It was mild-dry and slightly wet. (7) 34.2-39 m above the bottom (after 32.4 kaBP) : the average value of particle diameter and susceptibility was 188.89 μm and 381.1×10^-6 SI, and the annual average temperature and precipitation was about 4.4 ℃ and 330 mm. The climate was warm and dry. There shows a high comparability between these climate changes in the studied area and the regional environmental evolution. PhaseⅠcorresponds to the warm MIS (marine isotope stage) 5; PhaseⅡandⅢ correspond to the cooling MIS4; Phase Ⅳ, Ⅴand Ⅵ correspond to the warm MIS3; Phase Ⅶ corresponds to the cooling MIS2. Compared with adjacent areas, like Jiuzhoutai in Lanzhou Province and core RM in Zoige, the climate is obvious warmer and wetter in Linxia during the same period.
- Lintao County, Gansu Province /
- late Pleistocene /
- loess /
- environmental evolution

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图 1 甘肃临洮塔湾剖面黄土-古土壤序列粒度变化曲线图

Ⅰ.温暖较湿; Ⅱ.温干; Ⅲ.温干偏湿; Ⅳ.温干; Ⅴ.温暖较湿; Ⅵ.温干偏湿; Ⅶ.温凉干旱

Fig. 1. Grain-size varation in the loess sequence at Tawan, Lintao County, Gansu Province

下载: 全尺寸图片幻灯片

图 2 甘肃临洮塔湾剖面黄土-古土壤序列磁化率、古降水量与古温度变化曲线图

Ⅰ.温暖较湿; Ⅱ.温干; Ⅲ.温干偏凉; Ⅳ.温干偏湿; Ⅴ.温干偏凉; Ⅵ.温干偏湿; Ⅶ.温干

Fig. 2. Curves of magnetic susceptibility, paleo-precipitation and paleo-temperature in the loess-paleosol sequence at Tawan, Lintao County, Gansu Province

下载: 全尺寸图片幻灯片

图 3 甘肃临洮塔湾剖面黄土-古土壤序列多指标综合对比图

Ⅰ.温暖较湿; Ⅱ.温干; Ⅲ.温干偏凉; Ⅳ.温干偏湿; Ⅴ.温干偏凉; Ⅵ.温干偏湿; Ⅶ.温干

Fig. 3. Comprehensive comparation of multi-indexes in the loess-paleosol sequence at Tawan, Lintao County, Gansu Province

下载: 全尺寸图片幻灯片

表 1 甘肃临洮塔湾剖面黄土-古土壤序列粒度分析结果

Table 1. Granularity analysis results of the loess-paleosol sequence at Tawan, Lintao County, Gansu Province

表 2 甘肃临洮塔湾剖面黄土-古土壤序列磁化率测试数据(单位: 10^-6SI)

Table 2. Tested data of magnetic susceptibility of loess-paleosol sequence at Tawan, Lintao Conuty, Gansu Province

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