生态环境学报
生態環境學報
생태배경학보
ECOLOGY AND ENVIRONMENT
2013年
9期
1602-1607
,共6页
欧阳婷萍%卞勇%田成静%匡耀求%黄宁生%朱照宇%陈登强%李国敏%吴丹
歐暘婷萍%卞勇%田成靜%劻耀求%黃寧生%硃照宇%陳登彊%李國敏%吳丹
구양정평%변용%전성정%광요구%황저생%주조우%진등강%리국민%오단
云浮硫铁矿%土壤剖面%磁学性质%影响因素
雲浮硫鐵礦%土壤剖麵%磁學性質%影響因素
운부류철광%토양부면%자학성질%영향인소
Yunfu pyrite%soil profile%magnetic properties%influencing factor
广泛分布的硫铁矿在开采利用过程中可通过多种途径对矿区及周边环境产生严重影响,污染物产生的机制和迁移途径等成为学术界关注的焦点。近年来,环境磁学以其快速、经济、无损等优点被广泛应用于环境污染、物源分析等研究领域。本文对云浮硫铁矿矿区附近一个菜地土壤剖面进行详细的磁学测试,得到低频磁化率、频率磁化率、非磁滞剩磁磁化率、饱和等温剩磁及S比值等一系列磁学指标结果,并分析这些指标的剖面变化特征及指标间的相关关系,探讨影响土壤剖面磁学性质变化的主要因素,结果表明:低频磁化率、非磁滞剩磁磁化率和饱和等温剩磁在剖面底部(30 cm以下)基本稳定并且其值保持在较低的水平,其平均值分别为5.32×10-8 m3·kg-1、13.70×10-8 m3·kg-1和3.66×10-3 Am2·kg-1;上述指标在表层30 cm的平均值分别为32.97×10-8 m3·kg-1、86.21×10-8 m3·kg-1和5.39×10-3 Am2·kg-1,土壤剖面30 cm以上部分土壤明显受外来细颗粒磁性矿物的影响,磁性被显著增强。不同深度土壤中磁性矿物种类存在明显区别,剖面中部的高SIRM/χ值(70~100 kA·m-1)指示有胶黄铁矿等铁硫化物的存在。磁学参数之间的相关分析发现,剖面土壤中的铁硫化物及其中的单畴磁性颗粒是影响土壤磁学性质的主要因素。由于磁性矿物可通过吸附、共沉积、晶格置换等多种形式使多种重金属在土壤中富集,较大范围、多手段针对多种环境介质的磁学深入研究有望为硫铁矿周边重金属污染的产生机制和迁移路径研究开拓新途径。
廣汎分佈的硫鐵礦在開採利用過程中可通過多種途徑對礦區及週邊環境產生嚴重影響,汙染物產生的機製和遷移途徑等成為學術界關註的焦點。近年來,環境磁學以其快速、經濟、無損等優點被廣汎應用于環境汙染、物源分析等研究領域。本文對雲浮硫鐵礦礦區附近一箇菜地土壤剖麵進行詳細的磁學測試,得到低頻磁化率、頻率磁化率、非磁滯剩磁磁化率、飽和等溫剩磁及S比值等一繫列磁學指標結果,併分析這些指標的剖麵變化特徵及指標間的相關關繫,探討影響土壤剖麵磁學性質變化的主要因素,結果錶明:低頻磁化率、非磁滯剩磁磁化率和飽和等溫剩磁在剖麵底部(30 cm以下)基本穩定併且其值保持在較低的水平,其平均值分彆為5.32×10-8 m3·kg-1、13.70×10-8 m3·kg-1和3.66×10-3 Am2·kg-1;上述指標在錶層30 cm的平均值分彆為32.97×10-8 m3·kg-1、86.21×10-8 m3·kg-1和5.39×10-3 Am2·kg-1,土壤剖麵30 cm以上部分土壤明顯受外來細顆粒磁性礦物的影響,磁性被顯著增彊。不同深度土壤中磁性礦物種類存在明顯區彆,剖麵中部的高SIRM/χ值(70~100 kA·m-1)指示有膠黃鐵礦等鐵硫化物的存在。磁學參數之間的相關分析髮現,剖麵土壤中的鐵硫化物及其中的單疇磁性顆粒是影響土壤磁學性質的主要因素。由于磁性礦物可通過吸附、共沉積、晶格置換等多種形式使多種重金屬在土壤中富集,較大範圍、多手段針對多種環境介質的磁學深入研究有望為硫鐵礦週邊重金屬汙染的產生機製和遷移路徑研究開拓新途徑。
엄범분포적류철광재개채이용과정중가통과다충도경대광구급주변배경산생엄중영향,오염물산생적궤제화천이도경등성위학술계관주적초점。근년래,배경자학이기쾌속、경제、무손등우점피엄범응용우배경오염、물원분석등연구영역。본문대운부류철광광구부근일개채지토양부면진행상세적자학측시,득도저빈자화솔、빈솔자화솔、비자체잉자자화솔、포화등온잉자급S비치등일계렬자학지표결과,병분석저사지표적부면변화특정급지표간적상관관계,탐토영향토양부면자학성질변화적주요인소,결과표명:저빈자화솔、비자체잉자자화솔화포화등온잉자재부면저부(30 cm이하)기본은정병차기치보지재교저적수평,기평균치분별위5.32×10-8 m3·kg-1、13.70×10-8 m3·kg-1화3.66×10-3 Am2·kg-1;상술지표재표층30 cm적평균치분별위32.97×10-8 m3·kg-1、86.21×10-8 m3·kg-1화5.39×10-3 Am2·kg-1,토양부면30 cm이상부분토양명현수외래세과립자성광물적영향,자성피현저증강。불동심도토양중자성광물충류존재명현구별,부면중부적고SIRM/χ치(70~100 kA·m-1)지시유효황철광등철류화물적존재。자학삼수지간적상관분석발현,부면토양중적철류화물급기중적단주자성과립시영향토양자학성질적주요인소。유우자성광물가통과흡부、공침적、정격치환등다충형식사다충중금속재토양중부집,교대범위、다수단침대다충배경개질적자학심입연구유망위류철광주변중금속오염적산생궤제화천이로경연구개탁신도경。
The mine and utilization of widespread pyrite can produce serious impacts on mining area and the surrounding environment through various ways. The producing mechanism and transportation route of pollutants have been becoming a focus of pollution research for pyrite areas. Recently, environmental magnetism has been widely used in many research fields such as environmental pollution and provenance analysis due to its advantages of rapid, economic and nondestructive. Detailed magnetic investigation was performed for a soil profile covered by vegetables within the Yunfu pyrite zone in the present study. Analytical results of magnetic parameters low frequency magnetic susceptibility (χlf), frequency dependent magnetic susceptibility (χfd), anhysteresis remanent magnetic susceptibility (χARM), saturation isothermal remanent magnetization (SIRM) and S-ratio were acquired for all soil samples. Both vertical variation and correlationship of these parameters were analyzed. Main influencing factor for magnetic vertical variation was discussed for the studied soil profile. The results showed that low frequency magnetic susceptibility, anhysteresis remanent magnetic susceptibility and saturation isothermal remanent magnetization were basically stable and remained low level at the bottom of the soil profile (below 30 cm). The average values of these parameters were 5.32×10-8 m3·kg-1,13.70×10-8 m3·kg-1 and 3.66×10-3 Am2·kg-1, respectively. However, the average values of the mentioned parameters for the upper 30 cm increased to 32.97×10-8 m3·kg-1,86.21×10-8 m3·kg-1and 5.39×10-3 Am2·kg-1, respectively. Upper 30 cm of the soil profile was obviously influenced by external fine particles of magnetic minerals. As a result, magnetic properties of upper 30 cm were significantly enhanced. Magnetic mineral composition within soils differed through different depths. The high SIRM/χvalues (70-100 kA·m-1) of middle part of the soil profile indicated the presence of iron sulfide such as greigite. Correlation analysis of magnetic parameters indicated that single-domain iron sulfides predominates the magnetic properties through the soil profile. Detailed magnetic study of large scale and multi means for various environmental media is expected to provide an effective approach for the generation mechanism and migration path of heavy metal pollution for pyrite zone and its surrounding area since heavy metal can be enriched in soil through adsorption, co-deposition and lattice displacement by magnetic minerals.