第四纪研究
第四紀研究
제사기연구
2009年
6期
1154-1161
,共8页
秦小光%蔡炳贵%穆燕%宁波%殷志强
秦小光%蔡炳貴%穆燕%寧波%慇誌彊
진소광%채병귀%목연%저파%은지강
黄土粉尘%搬运距离%风力强度%物理模型
黃土粉塵%搬運距離%風力彊度%物理模型
황토분진%반운거리%풍력강도%물리모형
loess dust%dust transport distance%wind intensity%physical model
通过对黄土粉尘重力沉降过程的动力学分析,给出了黄土粉尘粒度分布的数学表达,讨论了粉尘沉积通量随搬运距离、粒径变化的物理过程,首次确定了估算粉尘搬运距离和风力强度的计算方法,为区分粉尘搬运距离和风力强度对粒度的影响及其它们在冰期间冰期中的差异提供了物理学的判别依据.分析结果表明:1)在重力沉降作用下,粉尘沉降通量随搬运距离的变化服从几何分布,具有沉降通量随搬运距离的增加迅速减小,越粗的粉尘颗粒其沉降通量初值越大,同时下降速度也越迅速的特点;2)如果用携粉尘气流的水平通量作代表风力强度,则粉尘搬运距离与粒度分布曲线上重力沉降部分最高点的粉尘沉降通量成反比,风力强度与该点对应粒径的平方和粉尘搬运距离成正比.因此,根据该点的粉尘沉降通量和对应粒径.可以估算粉尘的搬运距离和风力强度.根据上述理论对渭南阳郭中学S_0~L_1黄土-古土壤剖面进行了粉尘搬运距离和风力强度的估算:首先,从粒度分布中提取出3个对数正态分布的独立组份;然后利用粗粒组份的参数计算粉尘搬运距离和风力强度.分析结果表明粉尘搬运距离具有冰期近、间冰期远的特点,风力强度的变化则具有冰期弱、间冰期强的特点,LGM时段的风力强度比MIS 3阶段大,但小于全新世适宜期,而LGM时期粉尘搬运距离并未明显减小,因此,可能黄土粒度的变化并非反映了冬季风的变化,而是反映了夏季风的变化,夏季风是通过影响粉尘源区来影响粉尘粒度的变化.
通過對黃土粉塵重力沉降過程的動力學分析,給齣瞭黃土粉塵粒度分佈的數學錶達,討論瞭粉塵沉積通量隨搬運距離、粒徑變化的物理過程,首次確定瞭估算粉塵搬運距離和風力彊度的計算方法,為區分粉塵搬運距離和風力彊度對粒度的影響及其它們在冰期間冰期中的差異提供瞭物理學的判彆依據.分析結果錶明:1)在重力沉降作用下,粉塵沉降通量隨搬運距離的變化服從幾何分佈,具有沉降通量隨搬運距離的增加迅速減小,越粗的粉塵顆粒其沉降通量初值越大,同時下降速度也越迅速的特點;2)如果用攜粉塵氣流的水平通量作代錶風力彊度,則粉塵搬運距離與粒度分佈麯線上重力沉降部分最高點的粉塵沉降通量成反比,風力彊度與該點對應粒徑的平方和粉塵搬運距離成正比.因此,根據該點的粉塵沉降通量和對應粒徑.可以估算粉塵的搬運距離和風力彊度.根據上述理論對渭南暘郭中學S_0~L_1黃土-古土壤剖麵進行瞭粉塵搬運距離和風力彊度的估算:首先,從粒度分佈中提取齣3箇對數正態分佈的獨立組份;然後利用粗粒組份的參數計算粉塵搬運距離和風力彊度.分析結果錶明粉塵搬運距離具有冰期近、間冰期遠的特點,風力彊度的變化則具有冰期弱、間冰期彊的特點,LGM時段的風力彊度比MIS 3階段大,但小于全新世適宜期,而LGM時期粉塵搬運距離併未明顯減小,因此,可能黃土粒度的變化併非反映瞭鼕季風的變化,而是反映瞭夏季風的變化,夏季風是通過影響粉塵源區來影響粉塵粒度的變化.
통과대황토분진중력침강과정적동역학분석,급출료황토분진립도분포적수학표체,토론료분진침적통량수반운거리、립경변화적물리과정,수차학정료고산분진반운거리화풍력강도적계산방법,위구분분진반운거리화풍력강도대립도적영향급기타문재빙기간빙기중적차이제공료물이학적판별의거.분석결과표명:1)재중력침강작용하,분진침강통량수반운거리적변화복종궤하분포,구유침강통량수반운거리적증가신속감소,월조적분진과립기침강통량초치월대,동시하강속도야월신속적특점;2)여과용휴분진기류적수평통량작대표풍력강도,칙분진반운거리여립도분포곡선상중력침강부분최고점적분진침강통량성반비,풍력강도여해점대응립경적평방화분진반운거리성정비.인차,근거해점적분진침강통량화대응립경.가이고산분진적반운거리화풍력강도.근거상술이론대위남양곽중학S_0~L_1황토-고토양부면진행료분진반운거리화풍력강도적고산:수선,종립도분포중제취출3개대수정태분포적독립조빈;연후이용조립조빈적삼수계산분진반운거리화풍력강도.분석결과표명분진반운거리구유빙기근、간빙기원적특점,풍력강도적변화칙구유빙기약、간빙기강적특점,LGM시단적풍력강도비MIS 3계단대,단소우전신세괄의기,이LGM시기분진반운거리병미명현감소,인차,가능황토립도적변화병비반영료동계풍적변화,이시반영료하계풍적변화,하계풍시통과영향분진원구래영향분진립도적변화.
In this paper, the dynamic mechanism of the dust gravity settling process was analyzed, the mathematic expression of loess grain size distribution was studied, and physical relationships among dust deposition flux, dust-transport distance, wind intensity and dust grain-size was analyzed. A physical model that can estimate the dust transport distance and the wind intensity was firstly developed to distinguish their impacts on the grain size of the transported dusts during the glacial-interglacial transition. The dynamic analyses of dust gravity settling came to two conclusions. One is that the dust deposition flux varies with the dust transport distance,that is,the dust deposition flux decreases rapidly as the dust transport distance increases and the coarser the dust particle is, the larger the initial value of dust deposition flux and dust settling velocity are. Another is that if the wind intensity is expressed by the horizontal flux of the dust-carried air current,the dust transport distance is inversely proportional to the dust deposition flux at the highest point of the gravitational settlement dominated grain-size distribution curve and the wind intensity is proportional to the dust transport distance and the square of the grain size at this highest point. Therefore,the dust transport distance and the wind intensity can be estimated according to such a highest point. The two conclusions were applied in analysis of a S_o ~ L_1 loess-paleosol section accumulated in the last 60ka. The section is located in Yangge Town of Weinan County. Three independent modes with logarithmic normal distribution were first extracted from the grain size distribution of loess and paleosol samples. Then the dust transport distance and the wind intensity were estimated by using parameters of the coarse mode. The results show that the dust transport distance was shorter during the glacial period and longer during the Early Holocene. And the wind intensity was weaker during the glacial period and stronger in the Early Holocene. The wind intensity was larger in the LGM than in the MIS 3 stage but lower than during the Early Holocene. It is the dust source distance but not the wind intensity that may be the major factor to affect the loess grain size. This implies that the grain size of loess and paleosol may indicate the fluctuation of summer monsoon but not the fluctuation of winter monsoon. As the Eastern Asian summer monsoon concerns, its affecting loess grain size should be completed by impacting the vegetation of the dust source and in turn leading the dust source to advance and retreat.