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草业学报 ›› 2017, Vol. 26 ›› Issue (6): 45-55.DOI: 10.11686/cyxb2016456

• 研究论文 • 上一篇    下一篇

籽粒苋与烟草间作后还田对烟草钾吸收和土壤钾有效性的影响

吴凯1,2, 陈国军1,3, 闫慧峰1, 张永春4, 温亮4, 张超4, 孙延国1, 刘海伟1, 石屹1,*   

  1. 1.中国农业科学院烟草研究所,农业部烟草生物学与加工重点实验室,山东 青岛 266101;
    2.中国农业科学院研究生院,北京 100081;
    3.广东中烟工业有限公司,广东 韶关 512000;
    4.山东省临沂烟草公司,山东 临沂 276200
  • 收稿日期:2016-12-07 修回日期:2017-02-23 出版日期:2017-06-20 发布日期:2017-06-20
  • 通讯作者: E-mail:shiyi@caas.cn
  • 作者简介:吴凯(1990-),男,山东滨州人,在读硕士。E-mail:kkw0124@163.com
  • 基金资助:
    公益性行业(农业)科研专项经费项目(201203091)和中国农业科学院科技创新工程(ASTIP-TRIC03)资助

Returning effects on tobacco potassium uptake and soil potassium availability in grain amaranth-tobacco intercropping system

WU Kai1,2, CHEN Guo-Jun1,3, YAN Hui-Feng1, ZHANG Yong-Chun4, WEN Liang4, ZHANG Chao4, SUN Yan-Guo1, LIU Hai-Wei1, SHI Yi1,*   

  1. 1.Institute of Tobacco Research of CAAS, Key Laboratory of Tobacco Biology and Processing, Ministry of Agriculture, Qingdao 266101, China;
    2.Graduate School of Chinese Academy of Agricultural Science, Beijing 100081, China;
    3.China Tobacco Guangdong Industrial Co. Ltd, Shaoguan 512000, China;
    4.Linyi Tobacco Corporation, Linyi 276200, China
  • Received:2016-12-07 Revised:2017-02-23 Online:2017-06-20 Published:2017-06-20

摘要: 为研究籽粒苋与烟草间作对烟草发育和钾吸收的影响,通过两年大田试验,分别设置了籽粒苋间作不翻压和45 d后翻压、籽粒苋2行、4行、6行种植的处理,分析了不同间作模式下烟草干物质累积量、钾含量和钾吸收量的差异及土壤速效钾含量和缓效钾含量的差异。结果表明,籽粒苋与烟草间作后不翻压还田,烟草根系干物质积累量显著增加,钾含量无显著变化,含钾量增加70%,茎和叶片的干物质积累量分别下降了11%和14%,钾含量下降了0.11个百分点和0.12个百分点,含钾量下降了26%和12%。籽粒苋与烟草间作后翻压还田后,各处理的烟草叶片的钾含量均增加;与对照相比,2行籽粒苋(A2)处理和4行籽粒苋(A3)处理提高了烟草根系、茎和上部叶、中部叶的干物质积累量和含钾量,6行籽粒苋(A4)处理烟草、茎、上部叶、中部叶和下部叶、根系的干物质积累量和含钾量均降低;A2处理的上部叶和中部叶的干物质积累量低于A3处理,钾含量和含钾量高于A3处理。间作籽粒苋处理相比烟草单作,烟草行的土壤速效钾含量提高,土壤缓效钾含量变化不大;籽粒苋翻压还田的处理土壤速效钾含量显著大于不翻压还田的处理;籽粒苋翻压还田后烟草行的土壤速效钾的增加量以A4处理最大,翻压还田20和60 d后分别比对照高91%和35%,其次为A3处理,翻压还田20和60 d后分别比对照高54%和23%。不同处理间籽粒苋钾的表观流向存在差异,A2和A3处理籽粒苋42%~52%钾被烟草吸收,A4处理籽粒苋仅17%的钾被烟草吸收。综合得,烟草-籽粒苋间作可提高烟草叶片的钾含量和土壤速效钾含量,其中以距烟草行1 m处种植两行籽粒苋并于45~55 d时翻压还田的种植模式为较好。

Abstract: Two field experiments were conducted to explore the influence of grain amaranth (Amaranthus hypochondriacus) and tobacco intercropping on tobacco growth and potassium uptake during 2014 and 2015. The experiment during 2014 included three treatments, (a) planting tobacco only; (b) tobacco and amaranth intercropping, amaranth was cut and burried into soil after 45 day growth; (c) tobacco and amaranth intercropping, but did not cut and burry. There were 4 treatments during 2015, (d) planting tobacco only; The other 3 treatments were all tobacco and amaranth intercropping, (e) one row of tobacco with 2 rows of amaranth; (f) one row of tobacco with 4 rows of amaranth; (g) one row of tobacco with 6 rows of amaranth. We analyzed tobacco dry matter accumulation, tobacco potassium concentration, potassium uptake, soil available potassium and soil slow-release potassium in the three intercropping systems. The results showed that, compared with treatment (a), amaranth intercropping without returning to the field (treatment c) increased dry matter accumulation in tobacco roots. Potassium concentration showed no significant changes, while potassium content increased by 70%. Dry matter accumulation reduced by 11% and 14% respectively in stem and leaves, while potassium contents were 0.11% and 0.12% lower and potassium concentration 16% and 12% lower. For the treatments with amaranth returning to the field, the highest potassium concentration in leaves was recorded. The different intercropping systems showed different amounts of dry matter accumulation, potassium content and potassium concentration. Dry matter accumulation and potassium contents in root, stem, upper leaves and middle leaves increased in the 2 rows (e) and 4 rows (f) treatments and decreased in the 6 rows (g) treatment. Dry matter accumulation in the upper and middle leaves was lower in treatment (e) than (f), but the former's potassium concentration and potassium content were higher. The concentration of soil available potassium in the tobacco rows increased in the intercropping systems, but the concentration of soil slow-release potassium did not change. The intercropping systems without grain amaranth returning showed lower soil available potassium concentrations than those with amaranth returning. Among the treatments in the amaranth returning system, the growth in soil available potassium was largest in treatment (g), which increased by 91% and 35% when returned after 20 and 60 d respectively. Soil available potassium increased by 54% and 23% in (f) over these periods. The analysis of apparent potassium flow showed different results for the various amaranth returning systems. About 42%-52% of potassium was uptaken by the tobacco in treatments (e) and (f), while only some 17% was absorbed in treatment (g). This study suggests that the most favorable planting pattern is the amaranth-tobacco intercropping system with 2 rows of amaranths and returning amaranth to the field after 45-55 d growth.