不同供锌水平麦田小麦锌营养对土施锌肥的响应

doi:10.3864/j.issn.0578-1752.2024.14.010

中国农业科学 ›› 2024, Vol. 57 ›› Issue (14): 2815-2826.doi: 10.3864/j.issn.0578-1752.2024.14.010

• 土壤肥料·节水灌溉·农业生态环境 • 上一篇下一篇

不同供锌水平麦田小麦锌营养对土施锌肥的响应

黄婷苗¹^,²(), 陆乃昆¹, 解秉强¹, 曹寒冰³, 乔月静¹, 杨珍平¹, 高志强¹, 李廷亮³()

¹ 山西农业大学农学院/黄土高原特色作物优质高效生产省部共建协同创新中心，山西太谷 030801
² 西北农林科技大学资源环境学院/农业农村部西北植物营养与农业环境重点实验室，陕西杨凌 712100
³ 山西农业大学资源环境学院，山西太谷 030801

收稿日期:2024-02-08 接受日期:2024-04-08 出版日期:2024-07-16 发布日期:2024-07-24
通信作者:
李廷亮，E-mail：litingliang021@126.com
联系方式: 黄婷苗，E-mail：huangtingmiao@126.com。
基金资助:
国家重点研发计划(2021YFD1900700); 农业农村部西北植物营养与农业环境重点实验室基金(ZWYY-2023-03); 山西省高等学校科技创新项目(2021L167); 黄土高原特色作物优质高效生产省部共建协同创新中心自主研发项目(SBGJXTZX-42); 山西省科技创新人才团队专项(202304051001042); 山西农业大学科技创新基金(2020BQ72)

Response of Wheat Zinc Nutrition to Zinc Fertilization into Soils with Variable Available Zinc

HUANG TingMiao¹^,²(), LU NaiKun¹, XIE BingQiang¹, CAO HanBing³, QIAO YueJing¹, YANG ZhenPing¹, GAO ZhiQiang¹, LI TingLiang³()

¹ College of Agronomy, Shanxi Agricultural University/Ministerial and Provincial Co-Innovation Centre for Endemic Crops Production with High-quality and Efficiency in Loess Plateau, Taigu 030801, Shanxi
² College of Natural Resources and Environment, Northwest A&F University/Key Laboratory of Plant Nutrition and Agro-Environment in Northwest China, Ministry of Agriculture and Rural Affairs, Yangling 712100, Shaanxi
³ College of Resources and Environment, Shanxi Agricultural University, Taigu 030801, Shanxi

Received:2024-02-08 Accepted:2024-04-08 Published:2024-07-16 Online:2024-07-24

摘要/Abstract

摘要：

【目的】明确不同供锌麦田土壤有效锌和小麦籽粒锌含量对土施锌肥的响应，探索基于土壤有效锌实现小麦锌营养强化的调控措施，为优化田间锌肥管理、指导小麦丰产优质生产提供理论依据。【方法】在黄土高原东部的山西太谷（高锌麦田）和万荣（低锌麦田）分别开展两年田间定位试验，设置土施锌肥0、6、12、18、24 kg Zn·hm^-2，研究不同施锌量的高、低锌麦田小麦籽粒产量和锌含量、地上部锌吸收转移分配和土壤有效锌的变化特征。【结果】高、低锌麦田，土施不同量锌肥的小麦籽粒产量均无显著差异。高锌麦田，随锌肥用量增加，小麦籽粒锌含量增幅较小，第1年各处理间无显著差异。第2年，施锌处理的籽粒锌含量比不施锌增加了2.4%—11.0%；前后两年，无论施锌与否，籽粒锌含量均高于40 mg·kg^-1；与不施锌相比，锌转运系数_{秸秆-籽粒}、籽粒锌分配指数分别降低了23.9%—37.9%、4.3%—13.1%，地上部20%以上的锌残留在茎叶中。低锌麦田，籽粒锌含量和地上部各器官锌吸收量随锌肥用量增加而增加，锌转运系数_{秸秆-籽粒}则相反；相比不施锌处理，施锌处理的两年平均籽粒锌含量增加了9.4%—23.1%，锌转运系数_{秸秆-籽粒}降低了13.5%—24.5%，但各器官锌分配指数无显著差异。高、低锌麦田，土壤有效锌含量均随锌肥用量的增加而明显提升。回归分析表明，高锌麦田的土壤有效锌含量与籽粒锌含量呈二次曲线关系，低锌麦田为“线性+平台”关系，土壤有效锌含量增至4.12 mg·kg^-1时，籽粒锌含量最高，达34.76 mg·kg^-1。【结论】黄土高原东部一年一熟的小麦生产中，对于高锌麦田，应充分利用土壤有效锌，即使不施锌肥，也可实现小麦锌营养强化；低锌麦田，仅靠土施锌肥很难提升籽粒锌含量达到推荐值（40 mg·kg^-1），改善小麦锌营养可考虑通过土施锌肥使土壤有效锌含量提高至4 mg·kg^-1以上，并结合其他农艺措施，如叶面喷锌等。

关键词: 小麦, 土施锌肥, 土壤有效锌, 籽粒锌含量, 锌转运分配, 黄土高原

Abstract:

【Objective】 The objective of this study was to clarify the response of soil available zinc (Zn) and wheat grain Zn concentration to soil Zn fertilization under different Zn supply field conditions, and to explore the Zn fertilizer regulation measures for grain Zn fortification based on soil available Zn, so as to provide a scientific basis for optimizing Zn fertilizer application and achieving wheat grain with high-yield and high-quality. 【Method】 The two-year location-fixed field experiments with five Zn fertilizer application rates of 0, 6, 12, 18, and 24 kgZn·hm^-2 were carried out at Taigu (high-Zn field) and Wanrong (low-Zn field) of Shanxi Province in the eastern Loess Plateau, respectively. The wheat grain yield and Zn concentration, Zn uptake and its translocation and distribution in the aerial part, as well as soil available Zn were investigated in the high- and low-Zn fields. 【Result】 Grain yield was not affected by Zn fertilizer rates in both high- and low-Zn fields. In high-Zn field, a slight increase in grain Zn concentration was observed with the increase of Zn fertilizer rates. For grain Zn concentration, no significant difference existed among all treatments in the first year, while it was increased by 2.4%-11.0% for Zn fertilization treatments as compared with that of no Zn fertilization in the second year. The grain Zn concentration was higher than 40 mg·kg^-1for all treatments. Compared with Zn application, the Zn transfer factor from straw to grain and grain Zn portioning index were decreased by 23.9%-37.9% and 4.3%-13.1%, respectively, and more than 20% of shoot Zn still remained in the stems and leaves at wheat harvest. In low-Zn field, the grain Zn concentration and Zn uptake in each organ increased with increasing Zn rates, whereas the opposite trend was observed for Zn transfer factor from straw to grain. Compared with no Zn application, the grain Zn concentration averaged two years increased by 9.4%-23.1%, while the Zn transfer factor from straw to grain decreased by 13.5%-24.5%, but no obvious difference was found for Zn portioning index among five Zn rates. In both high- and low-Zn fields, the soil available Zn increased significantly with the added Zn fertilizer. The regression analysis showed that soil available Zn slightly increased grain Zn concentration, and the increase with available Zn could be described by a quadratic function in high-Zn field, and the linear-with-plateau model showed that the grain Zn plateau of 34.76 mg·kg^-1 was reached at the soil available Zn of 4.12 mg·kg^-1. 【Conclusion】 Therefore, for the purpose of achieving desirable grain Zn concentration of 40 mg·kg^-1 in the wheat monoculture aera of eastern Loess Plateau, it could be considered that higher soil available Zn played a critical role in the high-Zn field, and soil Zn fertilization could be considered to increase soil available Zn up to 4 mg·kg^-1 first, and then other agronomic measures such as foliar Zn application should not be ignored to address the gap between the current grain Zn concentration and the recommended value in the low-Zn field.

Key words: wheat, soil Zn application, soil available Zn, grain Zn concentration, Zn translocation and distribution, Loess Plateau

黄婷苗, 陆乃昆, 解秉强, 曹寒冰, 乔月静, 杨珍平, 高志强, 李廷亮. 不同供锌水平麦田小麦锌营养对土施锌肥的响应[J]. 中国农业科学, 2024, 57(14): 2815-2826.

HUANG TingMiao, LU NaiKun, XIE BingQiang, CAO HanBing, QIAO YueJing, YANG ZhenPing, GAO ZhiQiang, LI TingLiang. Response of Wheat Zinc Nutrition to Zinc Fertilization into Soils with Variable Available Zinc[J]. Scientia Agricultura Sinica, 2024, 57(14): 2815-2826.

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参考文献 42

[1]	STEVENS G A, BEAL T, MBUYA M N N, LUO H Q, NEUFELD L M, GROUP G M D R. Micronutrient deficiencies among preschool-aged children and women of reproductive age worldwide: A pooled analysis of individual-level data from population- representative surveys. The Lancet Global Health, 2022, 10(11): 1590-1599.
[2]	MCCLUNG J P. Iron, zinc, and physical performance. Biological Trace Element Research, 2019, 188(1): 135-139. doi: 10.1007/s12011-018-1479-7 pmid: 30112658
[3]	ZHAO F J. Soil and human health. European Journal of Soil Science, 2018, 69(1): 158.
[4]	CHEN X P, ZHANG Y Q, TONG Y P, XUE Y F, LIU D Y, ZHANG W, DENG Y, MENG Q F, YUE S C, YAN P, CUI Z L, SHI X J, GUO S W, SUN Y X, YE Y L, WANG Z H, JIA L L, MA W Q, HE M R, ZHANG X Y, KOU C L, LI Y T, TAN D S, CAKMAK I, ZHANG F S, ZOU C Q. Harvesting more grain zinc of wheat for human health. Scientific Reports, 2017, 7(1): 7016.
[5]	褚宏欣, 牟文燕, 党海燕, 王涛, 孙蕊卿, 侯赛宾, 黄婷苗, 黄倩楠, 石美, 王朝辉. 我国主要麦区小麦籽粒微量元素含量及营养评价. 作物学报, 2022, 48(11): 2853-2865. doi: 10.3724/SP.J.1006.2022.11099
	CHU H X, MU W Y, DANG H Y, WANG T, SUN R Q, HOU S B, HUANG T M, HUANG Q N, SHI M, WANG Z H. Evaluation on concentration and nutrition of micro-elements in wheat grains in major wheat production regions of China. Acta Agronomica Sinica, 2022, 48(11): 2853-2865. (in Chinese)
[6]	ZHAO A Q, ZHANG L S, NING P, CHEN Q, WANG B N, ZHANG F X, YANG X B, ZHANG Y L. Zinc in cereal grains: concentration, distribution, speciation, bioavailability, and barriers to transport from roots to grains in wheat. Critical Reviews in Food Science and Nutrition, 2022, 62(28): 7917-7928.
[7]	HUANG T M, HUANG Q N, SHE X, MA X L, HUANG M, CAO H B, HE G, LIU J S, LIANG D L, MALHI S S, WANG Z H. Grain zinc concentration and its relation to soil nutrient availability in different wheat cropping regions of China. Soil and Tillage Research, 2019, 191: 57-65.
[8]	LI C, GUO Z K, WANG X S, MA Y, LIU J S, SHI M, ZHANG D, MALHI S S, SIDDIQUE K H M, WANG Z H. Field-scale studies quantify limitations for wheat grain zinc biofortification in dryland areas. European Journal of Agronomy, 2023, 142: 126687.
[9]	CHEN Y L, MI H Z, ZHANG Y H, ZHANG G Y, LI C, YE Y, ZHANG R R, SHI J L, LI Z H, TIAN X H, WANG Y H. Impact of ZnSO₄ and ZnEDTA applications on wheat Zn biofortification, soil Zn fractions and bacterial community: significance for public health and agroecological environment. Applied Soil Ecology, 2022, 176: 104484.
[10]	李孟华, 王朝辉, 李强, 戴健, 高雅洁, 靳静静, 曹寒冰, 王森. 低锌旱地土施锌肥对小麦产量和锌利用的影响. 农业环境科学学报, 2013, 32(11): 2168-2174.
	LI M H, WANG Z H, LI Q, DAI J, GAO Y J, JIN J J, CAO H B, WANG S. Effects of soil Zn application on grain yield and Zn utilization of wheat in Zn-deficient dryland soils. Journal of Agro-Environment Science, 2013, 32(11): 2168-2174. (in Chinese)
[11]	LIU D Y, ZHANG W, PANG L L, ZHANG Y Q, WANG X Z, LIU Y M, CHEN X P, ZHANG F S, ZOU C Q. Effects of zinc application rate and zinc distribution relative to root distribution on grain yield and grain Zn concentration in wheat. Plant and Soil, 2017, 411(1): 167-178.
[12]	VAN EYNDE E, BREURE M S, CHIKOWO R, NJOROGE S, COMANS R N J, HOFFLAND E. Soil zinc fertilisation does not increase maize yields in 17 out of 19 sites in Sub-Saharan Africa but improves nutritional maize quality in most sites. Plant and Soil, 2023, 490(1): 67-91.
[13]	ZOU C Q, ZHANG Y Q, RASHID A, RAM H, SAVASLI E, ARISOY R Z, ORTIZ-MONASTERIO I, SIMUNJI S, WANG Z H, SOHU V, HASSAN M, KAYA Y, ONDER O, LUNGU O, MUJAHID M Y, JOSHI A K, ZELENSKIY Y, ZHANG F S, CAKMAK I. Biofortification of wheat with zinc through zinc fertilization in seven countries. Plant and Soil, 2012, 361(1): 119-130.
[14]	褚宏欣, 党海燕, 王涛, 孙蕊卿, 侯赛宾, 黄倩楠, 李小涵, 王朝辉, 黄婷苗. 我国主要麦区土壤有效铁锰铜锌丰缺状况评价及影响因素. 土壤学报, 2024, 61(1): 129-139.
	CHU H X, DANG H Y, WANG T, SUN R Q, HOU S B, HUANG Q N, LI X H, WANG Z H, HUANG T M. Evaluations and influencing factors of soil available Fe, Mn, Cu and Zn concentrations in major wheat production regions of China. Acta Pedologica Sinica, 2024, 61(1): 129-139. (in Chinese)
[15]	黄婷苗, 王朝辉, 黄倩楠, 侯赛宾. 黄淮麦区小麦籽粒锌含量差异原因与调控. 土壤学报, 2021, 58(6): 1496-1506.
	HUANG T M, WANG Z H, HUANG Q N, HOU S B. Causes and regulation of variation of zinc concentration in wheat grains produced in Huanghuai wheat production region of China. Acta Pedologica Sinica, 2021, 58(6): 1496-1506. (in Chinese)
[16]	KUTMAN U B, YILDIZ B, CAKMAK I. Effect of nitrogen on uptake, remobilization and partitioning of zinc and iron throughout the development of durum wheat. Plant and Soil, 2011, 342(1): 149-164.
[17]	鲍士旦. 土壤农化分析. 3版. 北京: 中国农业出版社, 2000.
	BAO S D. Soil and Agricultural Chemistry Analysis. 3rd ed. Beijing: China Agriculture Press, 2000. (in Chinese)
[18]	WANG J W, MAO H, ZHAO H B, HUANG D L, WANG Z H. Different increases in maize and wheat grain zinc concentrations caused by soil and foliar applications of zinc in Loess Plateau, China. Field Crops Research, 2012, 135: 89-96.
[19]	WANG Z M, LIU Q, PAN F, YUAN L X, YIN X B. Effects of increasing rates of zinc fertilization on phytic acid and phytic acid/zinc molar ratio in zinc bio-fortified wheat. Field Crops Research, 2015, 184: 58-64.
[20]	CAKMAK I, KALAYCI M, KAYA Y, TORUN A A, AYDIN N, WANG Y, ARISOY Z, ERDEM H, YAZICI A, GOKMEN O, OZTURK L, HORST W J. Biofortification and localization of zinc in wheat grain. Journal of Agricultural and Food Chemistry, 2010, 58(16): 9092-9102. doi: 10.1021/jf101197h pmid: 23654236
[21]	王孝忠, 田娣, 邹春琴. 锌肥不同施用方式及施用量对我国主要粮食作物增产效果的影响. 植物营养与肥料学报, 2014, 20(4): 998-1004.
	WANG X Z, TIAN D, ZOU C Q. Yield responses of the main cereal crops to the application approaches and rates of zinc fertilizer in China. Journal of Plant Nutrition and Fertilizers, 2014, 20(4): 998-1004. (in Chinese)
[22]	李昭敏. 优化施磷配施锌硒肥改善旱地冬小麦籽粒锌硒营养的效果研究[D]. 杨凌: 西北农林科技大学, 2023.
	LI Z M. Effect of optimal phosphorus application combined with zinc and selenium fertilizer on zinc and selenium nutrition of dryland winter wheat grain[D]. Yangling: Northwest A&F University, 2023. (in Chinese)
[23]	MARSCHNER H, MARSCHNER P. Marschner’s Mineral Nutrition of Higher Plants. 3rd ed. Amsterdam: Academic Press, 2012.
[24]	OLSEN L I, PALMGREN M G. Many rivers to cross: the journey of zinc from soil to seed. Frontiers in Plant Science, 2014, 5: 30. doi: 10.3389/fpls.2014.00030 pmid: 24575104
[25]	陈艳龙, 贾舟, 师江澜, 刘珂, 王少霞, 田霄鸿. 秸秆还田对石灰性土壤Zn扩散迁移及形态转化的影响. 土壤学报, 2018, 55(3): 721-733.
	CHEN Y L, JIA Z, SHI J L, LIU K, WANG S X, TIAN X H. Effect of straw return on diffusion, translocation and transformation of zinc in calcareous soil. Acta Pedologica Sinica, 2018, 55(3): 721-733. (in Chinese)
[26]	INAGAKI T M, DE MORAES SÁ J C, TORMENA C A, DRANSKI A, MUCHALAK A, BRIEDIS C, DE OLIVEIRA FERREIRA, GIAROLA N F B, DA SILVA A P. Mechanical and biological chiseling impacts on soil organic C stocks, root growth, and crop yield in a long-term no-till system. Soil and Tillage Research, 2021, 211: 104993.
[27]	张勇, 郝元峰, 张艳, 何心尧, 夏先春, 何中虎. 小麦营养和健康品质研究进展. 中国农业科学, 2016, 49(22): 4284-4298. doi: 10.3864/j.issn.0578-1752.2016.22.003.
	ZHANG Y, HAO Y F, ZHANG Y, HE X Y, XIA X C, HE Z H. Progress in research on genetic improvement of nutrition and health qualities in wheat. Scientia Agricultura Sinica, 2016, 49(22): 4284-4298. doi: 10.3864/j.issn.0578-1752.2016.22.003. (in Chinese)
[28]	ZHANG Y, SONG Q C, YAN J, TANG J W, ZHAO R R, ZHANG Y Q, HE Z H, ZOU C Q, ORTIZ-MONASTERIO I. Mineral element concentrations in grains of Chinese wheat cultivars. Euphytica, 2010, 174(3): 303-313.
[29]	YANG J, XU J F, WANG Z L, ZHANG X M, GUO Z K, WANG L, LIU C R, SUN Q, LI C, CHEN Y L, SHI M, WANG Z H. High-Zn wheat alleviates P-Zn antagonism by improving Zn activation, acquisition, and translocation at key growth stages. Field Crops Research, 2023, 304: 109149.
[30]	GUO Z K, ZHANG X M, WANG L, WANG X S, WANG R Z, HUI X L, WANG S, WANG Z H, SHI M. Selecting high zinc wheat cultivars increases grain zinc bioavailability. Journal of Agricultural and Food Chemistry, 2021, 69(38): 11196-11203. doi: 10.1021/acs.jafc.1c03166 pmid: 34528796
[31]	LIU D Y, ZHANG W, YAN P, CHEN X P, ZHANG F S, ZOU C Q. Soil application of zinc fertilizer could achieve high yield and high grain zinc concentration in maize. Plant and Soil, 2017, 411(1): 47-55.
[32]	CAKMAK I, KUTMAN U B. Agronomic biofortification of cereals with zinc: A review. European Journal of Soil Science, 2018, 69(1): 172-180.
[33]	KUTMAN U B, KUTMAN B Y, CEYLAN Y, ALI OVA E, CAKMAK I. Contributions of root uptake and remobilization to grain zinc accumulation in wheat depending on post-anthesis zinc availability and nitrogen nutrition. Plant and Soil, 2012, 361(1): 177-187.
[34]	LIU D Y, LIU Y M, ZHANG W, CHEN X P, ZOU C Q. Zinc uptake, translocation, and remobilization in winter wheat as affected by soil application of Zn fertilizer. Frontiers in Plant Science, 2019, 10: 426.
[35]	SPEROTTO R A, RICACHENEVSKY F K, WILLIAMS L E, VASCONCELOS M W, MENGUER P K. From soil to seed: micronutrient movement into and within the plant. Frontiers in Plant Science, 2014, 5: 438. doi: 10.3389/fpls.2014.00438 pmid: 25250035
[36]	XIA H Y, WANG L, QIAO Y T, KONG W L, XUE Y H, WANG Z S, KONG L G, XUE Y F, SIZMUR T. Elucidating the source-sink relationships of zinc biofortification in wheat grains: A review. Food and Energy Security, 2020, 9(4): 243.
[37]	CHEN Y L, SHI J L, DONG J, WU Y H, LI C, YE Y, TIAN X, WANG Y H. Synergistic improvement of soil organic carbon storage and wheat grain zinc bioavailability by straw return in combination with Zn application on the Loess Plateau of China. Catena, 2021, 197: 104920.
[38]	YANG N, WANG Z H, GAO Y J, ZHAO H B, LI K Y, LI F C, MALHI S S. Effects of planting soybean in summer fallow on wheat grain yield, total N and Zn in grain and available N and Zn in soil on the Loess Plateau of China. European Journal of Agronomy, 2014, 58: 63-72.
[39]	刘苡轩, 黄冬琳, 刘娜, 姚致远, 尹丹, 蒙元永, 赵护兵, 高亚军, 王朝辉. 渭北旱塬豆科绿肥提高冬小麦籽粒锌的效应与影响因素研究. 中国农业科学, 2018, 51(21): 4030-4039. doi: 10.3864/j.issn.0578-1752.2018.21.003.
	LIU Y X, HUANG D L, LIU N, YAO Z Y, YIN D, MENG Y Y, ZHAO H B, GAO Y J, WANG Z H. The increasing effect and influencing factors of leguminous green manure on wheat grain Zn in Weibei highland. Scientia Agricultura Sinica, 2018, 51(21): 4030-4039. doi: 10.3864/j.issn.0578-1752.2018.21.003. (in Chinese)
[40]	DIMKPA C O, ANDREWS J, SANABRIA J, BINDRABAN P S, SINGH U, ELMER W H, GARDEA-TORRESDEY J L, WHITE J C. Interactive effects of drought, organic fertilizer, and zinc oxide nanoscale and bulk particles on wheat performance and grain nutrient accumulation. The Science of the Total Environment, 2020, 722: 137808.
[41]	REHMAN A, FAROOQ M, OZTURK L, ASIF M, SIDDIQUE K H M. Zinc nutrition in wheat-based cropping systems. Plant and Soil, 2018, 422(1): 283-315.
[42]	赵娜, 赵护兵, 鱼昌为, 曹群虎, 李敏, 曹卫东, 高亚军. 旱地豆科绿肥腐解及养分释放动态研究. 植物营养与肥料学报, 2011, 17(5): 1179-1187.
	ZHAO N, ZHAO H B, YU C W, CAO Q H, LI M, CAO W D, GAO Y J. Nutrient releases of leguminous green manures in rainfed lands. Plant Nutrition and Fertilizer Science, 2011, 17(5): 1179-1187. (in Chinese)

试验点 Experimental site	pH	有机质 Organic matter (g·kg^-1)	全氮 Total N (g·kg^-1)	矿质氮 Mineral N (mg·kg^-1)	有效磷 Olsen-P (mg·kg^-1)	速效钾 Available K (mg·kg^-1)	有效锌 Available Zn (mg·kg^-1)
太谷 Taigu	8.43	25.9	11.3	48.3	19.5	151.2	8.11
万荣 Wanrong	8.44	9.71	0.58	6.17	8.15	115.6	0.51

小麦种植 Wheat growing	处理 Treatment	锌转运系数 Zn transfer factor		锌分配指数 Zn portioning index (%)
		（秸秆-籽粒） (Straw-grain)		籽粒 Grain		茎叶 Stem		颖壳 Glume
				高锌田块 High-Zn field	低锌田块 Low-Zn field	高锌田块 High-Zn field	低锌田块 Low-Zn field	高锌田块 High-Zn field	低锌田块 Low-Zn field	高锌田块 High-Zn field	低锌田块 Low-Zn field
第1年 The first year	Zn0	2.17 a	6.21 a	65.40 a	84.64 a	25.92 a	9.29 a	8.68 a	6.06 a
	Zn6	1.71 a	5.24 ab	61.31 a	82.75 a	31.75 a	11.67 a	6.94 a	5.58 a
	Zn12	1.93 a	4.85 b	61.80 a	82.85 a	30.79 a	11.06 a	7.41 a	6.09 a
	Zn18	1.85 a	4.91 b	60.12 a	81.97 a	32.01 a	12.43 a	7.87 a	5.60 a
	Zn24	1.85 a	4.49 b	63.99 a	81.31 a	28.61 a	12.98 a	7.40 a	5.71 a
第2年 The second year	Zn0	2.72 a	4.82 a	75.58 a	77.24 a	17.97 b	14.20 a	6.45 a	8.56 a
	Zn6	2.07 b	4.30 ab	71.74 ab	75.55 a	21.94 ab	14.76 a	6.32 a	9.69 a
	Zn12	2.06 b	3.74 b	69.71 ab	74.40 a	23.44 ab	16.14 a	6.86 a	9.45 a
	Zn18	2.05 b	4.02 ab	72.31 ab	74.25 a	20.79 ab	15.06 a	6.90 a	10.69 a
	Zn24	1.69 b	3.84 ab	65.66 b	73.63 a	27.99 a	15.45 a	6.35 a	10.93 a
变异来源 Source of variations
	年份Year	NS	NS	*	NS	*	*	NS	*
	处理Treatment	NS	*	NS	NS	NS	NS	NS	NS
	年份×处理 Year×Treatment	NS	NS	NS	NS	NS	NS	NS	NS

不同供锌水平麦田小麦锌营养对土施锌肥的响应

Response of Wheat Zinc Nutrition to Zinc Fertilization into Soils with Variable Available Zinc

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