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| 黄河上游河曲地区对流云催化增雨的数值模拟研究 | |
| 引用本文: | 王宏,雷恒池,李书严,德力格尔,李仑格,肖稳安,洪延超,黄美元.黄河上游河曲地区对流云催化增雨的数值模拟研究[J].气候与环境研究,2004,9(4):619-630. |
| 作者姓名: | 王宏 雷恒池 李书严 德力格尔 李仑格 肖稳安 洪延超 黄美元 |
| 作者单位: | 1. 中国气象科学院数值预报基地,北京,100081;中国科学院大气物理研究所中小尺度部,北京,100029 2. 中国科学院大气物理研究所中小尺度部,北京,100029 3. 青海省气象局人工影响天气办公室,西宁,810001 4. 南京气象学院,南京,210044 |
| 基金项目: | 青海省人工影响天气办公室"黄河上游人工增雨技术研究" |
| 摘 要: | 应用中国科学院大气物理研究所开发的三维对流云模式,对青藏高原河曲地区强对流云的催化增雨效果及催化云的动力特征、微物理机制进行了模拟研究.模拟结果显示:黄河上游河曲地区的对流云具备一定的催化潜力.如果催化时机、部位选择适当,降水总量增加有望达到30%~50%,催化所产生的动力效果比较显著.催化剂的加入使得云中凝华潜热释放量增加,上升气流加强,云顶升高,云水平尺度也有所加大,地面降水区域扩大,降水时间延长.由于云中冰晶大量生成,导致过冷云水、雨水减少,暖雨过程迅速减弱,云中霰和冻滴量增多,其融化过程加强引起的降水增加远远超过了暖雨量的减少,总的增雨效果比较显著.敏感性实验表明,催化高度对增雨效果的影响最为显著,高于某一催化高度,有可能产生增雨防雹的好效果;低于某一催化高度,则会在防雹的同时使地面降水减少.对流云早期催化的增雨效果较好.一定范围内催化剂量的变化对增雨量影响不大,小剂量催化也有可能达到较好的增雨效果. |
| 关 键 词: | 云模拟 动力特征 微物理机制 催化增雨 |
| 文章编号: | 1006-9585(2004)04-0619-12 |
| 修稿时间: | 2003年7月24日 |
The Seeding Experiments of Severe Convective Clouds Occurred in the Tibetan Plateau |
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| Wang Hong,Lei Hengchi,Li Shuyan,Deligeer,Li Lunge,Xiao Wenan,Hong Yanchao and Huang Meiyuan.The Seeding Experiments of Severe Convective Clouds Occurred in the Tibetan Plateau[J].Climatic and Environmental Research,2004,9(4):619-630. | |
| Authors: | Wang Hong Lei Hengchi Li Shuyan Deligeer Li Lunge Xiao Wenan Hong Yanchao and Huang Meiyuan |
| Abstract: | Using a 3-D convective cloud model with fully elastic primitive equations, a series of seeding experiments are done on convective clouds occurred in the Tibetan plateau. The results indicate that the convective clouds occurred in the Tibetan plateau have larger latent ability of seeding precipitation enhancement. Less dosage catalyst of AgI may increase 30%-50% of precipitation when seeding location and opportunity is correct. After convective clouds are seeded, the release of latent heat by deposition process, updraft and top of cloud increase distinctly, the horizontal scale and rainfall area of clouds are also enlarged. The number of Ice crystals increased greatly and thus lead to icy particles such as graupels and frozen droplets increase while supercooled water and hail decrease. Cold rain process is strengthened and warm rain process become weakened. The increasing of precipitation mainly comes from formation and melting process of graupel. |
| Keywords: | cloud model dynamical characteristics microphysics mechanism seeding experiment |
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