The study and application of eco-geological adaptibility model for Myricarubra in Longhai,Fujian Province
ZHAO Chen1,2,3,4(), SUN Bin-Bin1,2,3(), ZHOU Guo-Hua1,2,3, HE Ling1,2,3, ZENG Dao-Ming1,2,3
1. Key Laboratory of Geochemical Exploration,Ministry of Land and Resources,Langfang 065000,China 2. UNESCO International Center on Global-scale Geochemistry,Langfang 065000,China 3. Institute of Geophysical and Geochemical Exploration,Chinese Academy of Geological Sciences, Langfang 065000,China 4. College of Earth Sciences,Guilin University of Technology,Guilin 541004,China
High quality and high yield of famous agricultural products are often related to the specific eco-geological environment and geochemical conditions of the producing area.This paper develops the eco-geological and geochemical adaptibility model of Myricarubra in Longhai City. Geological and geochemical survey for famous producing area of Fugong bayberry were conducted.Theresults show that the geological background of the high-quality bayberry producing area in Longhai is granitoid, and the values of Mn, P, S, Zn, Al2O3, Na2O, K2O and available Mn, P, S in soil are relatively high, whilethe values of heavy metal elements such as As, Cd, Cr and Hg are low. The terrain of this area is hilly and mountainous with low elevation and low slope, and soil types are mainly red and yellow soil.According to the eco-geological model and on the basis of the data of 1∶50,000 soilquality geochemical survey, 1∶50,000 geological map as well as topographic, geomorphic and soil type maps of Longhai City, the suitable planting area of Myricarubra in Longhai was delineated, which involve 259.89 km2 optimum planting area and 70.62 km2 suitable planting area,which is about 5 times the existing planting area. These results could give geological and geochemical basis for planting planningof Myricarubra in Longhai City.
赵辰, 孙彬彬, 周国华, 贺灵, 曾道明. 福建龙海杨梅生态地质适生模型研究与应用[J]. 物探与化探, 2021, 45(5): 1121-1129.
ZHAO Chen, SUN Bin-Bin, ZHOU Guo-Hua, HE Ling, ZENG Dao-Ming. The study and application of eco-geological adaptibility model for Myricarubra in Longhai,Fujian Province. Geophysical and Geochemical Exploration, 2021, 45(5): 1121-1129.
① 土壤环境质量良好,无重金属污染(w(As)≤40×10-6、w(Cd)≤0.3×10-6、w(Cr)≤150×10-6、w(Cu)≤50×10-6、w(Hg)≤1.3×10-6、w(Ni)≤60×10-6、w(Pb)≤70×10-6、w(Zn)≤200×10-6); ② 土壤中K、P含量丰富(w(K)>20×10-3,w(P)>0.8×10-3),且Se含量适量或丰富(w(Se)>0.175×10-6); ③B、Mn、S、Zn等含量或有效量不缺乏(w(Mn)≤375×10-6、w(S)≤172×10-6、w(Zn)≤50×10-6、有效Mn含量≤1×10-6、有效S含量≤16×10-6、有效Zn含量≤0.3×10-6)。同时拥有全量及有效量数据时,以有效量评价结果为主
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适 宜
① 土壤环境质量良好,无重金属污染(w(As)≤40×10-6、w(Cd)≤0.3×10-6、w(Cr)≤150×10-6、w(Cu)≤50×10-6、w(Hg)≤1.3×10-6、w(Ni)≤60×10-6、w(Pb)≤70×10-6、w(Zn)≤200×10-6); ② 土壤中K、P含量不缺乏(10×10-3<w(K)≤20×10-3,0.4×10-3<w(P)≤0.8×10-3); ③ B、Mn、S、Zn等含量或有效量不缺乏(w(Mn)≤375×10-6、w(S)≤172×10-6、w(Zn)≤50×10-6、有效Mn含量≤1×10-6、有效S含量≤16×10-6、有效Zn含量≤0.3×10-6)。同时拥有全量及有效量数据时,以有效量评价结果为主
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