腐植酸钾和氨基酸肥料对砂培番茄生长与果实品质的影响

doi:10.7668/hbnxb.20194161

摘要/Abstract

摘要：

以番茄为试验材料,采用砂培的栽培方法,探究外源添加腐植酸钾和氨基酸肥料对番茄苗期代谢通路、植株生物量、茎叶果养分吸收量、产量和品质指标的影响。结果表明,腐植酸钾处理下番茄根长在苗期和开花结果期显著增加118%,13%,茎中氮、磷、钾携出量显著增加31%,45%,26%;叶中磷携出量显著增加92%;果实中磷携出量也显著增加45%。代谢组学结果表明,腐植酸钾处理主要影响番茄谷胱甘肽代谢、甘氨酸、丝氨酸和苏氨酸代谢、卟啉与叶绿素代谢,氨基酸肥料处理则主要影响番茄丙酸代谢、泛酸和辅酶A生物合成以及TCA循环。与空白对照相比,腐植酸钾处理下的番茄产量显著增加35%,地上部鲜质量和干质量显著增加21%,5%,同时也显著提高番茄果实中可溶性糖含量、糖酸比和可溶性固形物含量,增幅分别为30%,41%,0.39百分点。施用氨基酸肥料显著提高了番茄开花结果期的根长、地上部鲜质量和果实产量,其增幅分别为19%,18%,26%,番茄果实可溶性固形物含量提高0.30百分点,固酸比提升16%,单果质量提高15.6%。综上所述,腐植酸钾和氨基酸肥料的施用可显著改变砂培番茄植株碳氮代谢过程,促进番茄生长和果实品质的形成,是实现高产优质番茄栽培的有效农艺措施。

关键词: 番茄, 砂培, 腐植酸钾, 氨基酸肥料, 产量, 品质

Abstract:

Using tomato as experimental material and using sand cultivation method,the effects of exogenous addition of potassium humate and amino acid fertilizer on the metabolic pathway,plant biomass,nutrient uptake,yield and quality index of tomato at seedling stage were explored.The experimental results showed that:the root growth of tomato increased by 118% and 13% at the seedling stage and flowering and fruiting stage under potassium humate treatment,and the nitrogen,phosphorus and potassium carrying in the stem increased significantly by 31%,45% and 26%.The amount of phosphorus carried out in leaves increased significantly by 92%.Phosphorus carrying from fruit also increased significantly by 45%.The metabolomic results showed that potassium humate treatment mainly affected tomato glutathione metabolism,glycine serine and threonine metabolism,porphyrin and chlorophyll metabolism,while amino acid fertilizer treatment mainly affected tomato propionic acid metabolism,pantothenic acid and coenzyme A biosynthesis and TCA cycling.Compared with the blank control,the yield of tomatoes under potassium humate treatment increased by 35%,the fresh weight and dry weight of the aboveground increased by 21% and 5%,and the soluble sugar content,sugar-acid ratio and soluble solids content in tomato fruits were also significantly increased,with increases of 30%,41% and 0.39 percentage point,respectively.The application of amino acid fertilizer significantly increased the root length,aerial fresh weight and fruit yield of tomato during the flowering and fruiting stage,which increased by 19%,18% and 26%,respectively,and the soluble solids content of tomato fruit increased by 0.30 percentage point,the solid-acid ratio increased by 16%,and the weight per fruit increased by 15.6%.In summary,the application of potassium humate and amino acid fertilizer can significantly change the carbon and nitrogen metabolism process of sand tomato plants,promote tomato growth and fruit quality,and is an effective agronomic measure to achieve high-yield and high-quality tomato cultivation.

Key words: Tomato, Sand cultivation, Potassium humate, Amino acid fertilizer, Yield, Quality

陈琪, 董静, 周伟伟, 庞忠俊, 杨加仪, 梁斌. 腐植酸钾和氨基酸肥料对砂培番茄生长与果实品质的影响[J]. 华北农学报, 2023, 38(S1): 300-306. doi: 10.7668/hbnxb.20194161.

CHEN Qi, DONG Jing, ZHOU Weiwei, PANG Zhongjun, YANG Jiayi, LIANG Bin. Effects of Potassium Humate and Amino Acid Fertilizer on Growth and Fruit Quality of Sand Tomatoes[J]. Acta Agriculturae Boreali-Sinica, 2023, 38(S1): 300-306. doi: 10.7668/hbnxb.20194161.

http://www.hbnxb.net/CN/Y2023/V38/IS1/300

图/表 8

图1 腐植酸钾和氨基酸肥料对不同生育期生物量和产量的影响不同小写字母表示差异显著,P<0.05。

Fig.1 Effects of potassium humate and amino acid fertilizer on biomass and yield at different growth stages Different lowercase letters indicate significant differences,P<0.05.

表1 腐植酸钾和氨基酸肥料对番茄根系生长的影响

Tab.1 Effects of potassium humate and amino acid fertilizer on root growth

生育期 Reproductive period	处理 Treatment	总根长/m Total root length	根表面积/cm² Root surface area	根体积/cm³ Root volume	根平均直径/mm Average root diameter	根鲜质量/ (g/株) Root fresh quality
苗期	CK	22.29±0.32b	198.51±2.68b	1.41±0.02b	0.70±0.01b	1.77±0.26b
Seeding stage	ACF	18.42±2.30b	160.95±22.07b	1.12±0.17b	0.71±0.01b	1.94±0.47b
	KHM	40.24±7.19a	325.27±45.80a	2.10±0.24a	1.02±0.21a	2.97±0.18a
开花结果期	CK	46.21±4.23b	426.28±79.66ab	3.33±1.07a	1.11±0.30b	6.01±0.54b
Flowering stage	ACF	55.24±0.98a	410.84±36.14b	3.65±0.95a	1.47±0.14ab	7.90±1.71ab
	KHM	52.34±2.21a	538.92±84.74a	4.26±0.52a	1.53±0.30a	9.30±0.74a
成熟期	CK	100.09±10.32a	1 025.09±112.71a	7.63±1.60a	2.03±0.42a	13.30±1.38a
Maturity stage	ACF	105.78±4.36a	1 210.68±73.17a	8.39±0.45a	2.30±0.11a	13.13±1.52a
	KHM	113.68±10.83a	1 220.00±287.62a	8.80±2.53a	2.41±0.33a	14.27±1.60a

图2 不同处理的差异代谢物横坐标代表该组对比各物质的倍数变化(取以2为底的对数),纵坐标表示t检验的P-value(取以10为底对数的负数);散点大小代表OPLS-DA模型的VIP值,散点越大VIP值越大;显著上调的代谢物以红色表示,显著下调的代谢物以蓝色表示,非显著差异的代谢物为灰色。

Fig.2 Differential metabolites with different treatments The abscissa represents the multiple change of the group compared to each substance(take the logarithm with base 2),the ordinate represents the P-value of the t-test(take the negative number with the base 10 logarithm);the scatter size represents the VIP value of the OPLS-DA model;the larger the scatter,the larger the VIP value;significantly upregulated metabolites are indicated in red,significantly downregulated metabolites are indicated in blue,and non-significantly different metabolites are gray.

图3 差异代谢物代谢通路分析 1.苯丙氨酸代谢;2.丙氨酸代谢 ;3.泛酸和辅酶A生物合成;4.丙酸代谢;5.二羧酸代谢;6.丁酸代谢;7.酪氨酸代谢;8.TCA循环;9.丙氨酸、天冬氨酸和谷氨酸代谢;10.嘧啶代谢;11.苯丙素的生物合成。气泡图中每一个气泡代表一个代谢通路,气泡所在横坐标和气泡大小表示该通路在拓扑分析中的影响因子大小,大小越大影响因子越大。气泡所在纵坐标和气泡颜色表示富集分析的P值(取负自然对数,即-ln(p)),颜色越深P值越小,富集程度越显著。图4同。

Fig.3 Analysis of differential metabolite metabolic pathway 1.Phenylalanine metabolism;2.Beta-alanine metabolism;3.Pantothenate and CoA biosynthesis;4.Propanoate metabolism;5.Glyoxylate and dicarboxylate metabolism;6.Butanoate metabolism;7.Tyrosine metabolism;8.Citrate cycle;9.Alanine,aspartate angllutamate metabolism;10.Pyrimidine metabolism;11.Phenylpropanoid biosynthesis.Each bubble in the bubble chart represents a metabolic pathway, and the abscissa and bubble size of the bubble represent the size of the impact factor of the pathway in the topological analysis, and the larger the size, the larger the impact factor.The ordinate and bubble color of the bubble represent the P value of the enrichment analysis (take the negative natural logarithm, that is, -ln(p)), the darker the color, the smaller the P value, the more significant the enrichment.The same as Fig.4.

图4 差异代谢物代谢通路分析 1.苯丙氨酸代谢;2.氨基酸tRNA生物合成;3.丙氨酸、天冬氨酸和谷氨酸代谢;4.颉氨酸、亮氨酸和异亮氨酸生物合成; 5.谷胱甘肽代谢;6.卟啉和叶绿素代谢;7.甘氨酸、丝氨酸和苏氨酸代谢;8.不饱和脂肪酸的生物合成。

Fig.4 Analysis of differential metabolite metabolic pathway 1.Phenylalanine metabolism;2.Minoacyl-tRNA biosynthesis;3.Alanine,aspartate angllutamate metabolism;4.Valine,leucine and isoleucine biosynthesis;5.Valine,leucine and isoleucine biosynthesis;6.Porphyrin and chlorophyll metabolism;7.Glycine,serine and threonine metabolism;8.Biosynthesis of nsaturated fatty acids.

表2 腐植酸钾和氨基酸肥料对植株茎、叶和果氮、磷、钾养分含量的影响

Tab.2 Effects of potassium humate and amino acid fertilizer on the nutrient content of plant stem,leaf and fruit nitrogen,phosphorus and potassium %

生育期 Reproductive period	处理 Treatment	茎养分含量 Stem nutrient content			叶养分含量 Leaf nutrient content			果养分含量 Fruit nutrient content
生育期 Reproductive period	处理 Treatment	N	P₂O	K₂O	N	P₂O	K₂O	N	P₂O	K₂O
苗期	CK	3.16±0.18a	0.59±0.03b	9.45±0.41b	2.04±0.19b	0.91±0.02b	5.94±0.70a	—	—	—
Seeding stage	ACF	3.12±0.09a	0.52±0.04b	10.57±0.88ab	2.66±0.19b	0.89±0.03b	6.17±0.76a	—	—	—
	KHM	3.02±0.16a	0.71±0.07a	11.44±0.49a	4.26±0.82a	1.03±0.02a	6.71±0.86a	—	—	—
开花结果期	CK	3.98±0.18b	0.91±0.04b	3.74±0.45a	7.92±0.14a	1.11±0.02b	3.37±0.09ab	4.19±0.26a	1.17±0.14a	4.55±0.05a
Flowering stage	ACF	4.49±0.54ab	1.05±0.06b	3.52±0.11a	8.12±0.42a	1.39±0.08ab	2.98±0.41b	3.85±0.05b	1.16±0.12a	4.85±0.14a
	KHM	5.11±0.15a	1.26±0.16a	4.36±0.63a	8.26±0.24a	1.66±0.26a	3.69±0.22a	4.07±0.04ab	1.29±0.07a	4.36±0.91a
成熟期	CK	2.06±0.15a	0.91±0.04a	8.11±1.33a	3.53±0.10a	1.01±0.09b	7.81±0.83ab	3.35±0.22a	1.11±0.05b	3.60±0.39a
Maturity stage	ACF	2.09±0.16a	1.02±0.20a	7.09±0.61a	3.37±0.09a	0.99±0.04b	6.82±0.94b	3.36±0.08a	1.21±0.05ab	3.26±0.05a
	KHM	2.30±0.10a	1.11±0.06a	8.65±0.62a	3.54±0.21a	1.35±0.10a	8.49±0.40a	3.55±0.06a	1.30±0.05a	3.41±0.13a

表3 腐植酸钾和氨基酸肥料对植株茎、叶和果氮、磷、钾养分携出量的影响

Tab.3 Effects of potassium humate and amino acid fertilizer on the amount of nitrogen,phosphorus and potassium nutrients uptaked by plant stems,leaves and fruits g/株

生育期 Reproductive period	处理 Treatment	茎携出量 Stem nutrient uptake			叶携出量 Leaf nutrient uptake			果携出量 Fruit nutrient uptake
生育期 Reproductive period	处理 Treatment	N	P₂O	K₂O	N	P₂O	K₂O	N	P₂O	K₂O
苗期	CK	0.19±0.01b	0.04±0.01b	0.56±0.03b	0.13±0.02b	0.06±0.01b	0.37±0.02b	—	—	—
Seeding stage	ACF	0.21±0.02b	0.04±0.01b	0.70±0.10b	0.21±0.03b	0.07±0.01b	0.49±0.10b	—	—	—
	KHM	0.35±0.03a	0.08±0.02a	1.29±0.21a	0.53±0.20a	0.13±0.02a	0.81±0.05a	—	—	—
开花结果期	CK	1.91±0.04b	0.44±0.01b	1.80±0.23b	2.81±0.05a	0.40±0.01b	1.19±0.03ab	2.03±0.31a	0.56±0.04b	2.20±0.21a
Flowering stage	ACF	2.20±0.37ab	0.51±0.05ab	1.72±0.14b	2.83±0.18a	0.49±0.05ab	1.03±0.03b	2.01±0.27a	0.66±0.07ab	2.54±0.37a
	KHM	2.62±0.17a	0.65±0.11a	2.23±0.23a	2.88±0.19a	0.58±0.07a	1.29±0.09a	2.35±0.07a	0.74±0.02a	2.51±0.47a
成熟期	CK	1.32±0.16b	0.58±0.06b	2.58±0.27b	1.34±0.11b	0.39±0.06b	1.50±0.30b	5.08±0.56b	1.69±0.22b	5.71±0.21b
Maturity stage	ACF	1.32±0.17b	0.64±0.13ab	2.23±0.17b	1.50±0.06b	0.44±0.01b	1.51±0.14b	6.53±0.59a	2.36±0.33a	6.34±0.73a
	KHM	1.73±0.04a	0.84±0.10a	3.26±0.32a	1.97±0.27a	0.75±0.11a	2.37±0.30a	6.71±0.60a	2.45±0.22a	6.45±0.60a

表4 腐植酸钾和氨基酸肥料对番茄品质指标的影响

Tab.4 Effects of potassium humate and amino acid fertilizers on tomato quality

处理 Treatment	硬度/MPa Hardness	果型指数 Fruit type index	单果质量/g Single fruit weight	可溶性蛋白/(mg/g) Soluble protein	Vc含量/(mg/kg) Vc content
CK	0.38±0.02a	1.19±0.03b	86.08±7.34b	0.18±0.02a	187.11±10.05a
ACF	0.29±0.03b	1.18±0.02b	99.51±7.74a	0.17±0.01a	181.32±16.95a
KHM	0.32±0.02b	1.26±0.04a	97.50±4.69a	0.13±0.02b	143.48±8.92b
处理 Treatment	可溶性糖/(mg/g) Soluble sugars	有机酸/(mg/g) Organic acid	糖酸比 Sugar-to-acid ratio	可溶性固形物/% Soluble solids	固酸比 Solid-acid ratio
CK	31.92±1.18b	5.95±0.54a	5.39±0.55b	7.30±0.10b	12.30±0.93b
ACF	30.76±4.57b	5.35±0.31a	5.85±0.70b	7.60±0.17a	14.24±0.89a
KHM	41.55±2.29a	5.61±0.43a	7.62±0.80a	7.69±0.10a	13.76±0.95ab

参考文献 30

[1]	李君明, 项朝阳, 王孝宣, 国艳梅, 黄泽军, 刘磊, 李鑫, 杜永臣. “十三五” 我国番茄产业现状及展望[J]. 中国蔬菜, 2021(2):13-20.doi:10.19928/j.cnki.1000-6346.2021.2009.
	Li J M, Xiang C Y, Wang X X, Guo Y M, Huang Z J, Liu L, Li X, Du Y C. Current situation of tomato industry in China during' the thirteenth five-year plan' period and future prospect[J]. China Vegetables, 2021(2):13-20.
	孙锦, 李谦盛, 岳冬, 高洪波, 康云艳, 田婧, 李晶, 郭世荣. 国内外无土栽培技术研究现状与应用前景[J]. 南京农业大学学报, 2022, 45(5):898-915.doi:10.7685/jnau.202203045.
	Sun J, Li Q S, Yue D, Gao H B, Kang Y Y, Tian J, Li J, Guo S R. Research status and application prospects of soilless culture technology in the world[J]. Journal of Nanjing Agricultural University, 2022, 45(5):898-915.
[2]	蒋卫杰, 邓杰, 余宏军. 设施园艺发展概况、存在问题与产业发展建议[J]. 中国农业科学, 2015, 48(17):3515-3523.doi:10.3864/j.issn.0578-1752.2015.17.017.
	Jiang W J, Deng J, Yu H J. Development situation,problems and suggestions on industrial development of protected horticulture[J]. Scientia Agricultura Sinica, 2015, 48(17):3515-3523.
[3]	刘国秀, 沈宏. 生物刺激素及其在农业中的应用[J]. 磷肥与复肥, 2020, 35(11):5.doi:10.3969/j.issn.1007-6220.2020.11.008.
	Liu G X, Shen H. Biostimulants and their application in agriculture[J]. Phosphate & Compound Fertilizer, 2020, 35(11):5.
[4]	陈浩, 李煜博, 邵志勇, 郑积荣, 胡松申, 王同林, 刘丽红, 汪俏梅. 壳寡糖和油菜素甾醇处理对番茄产量和品质的影响[J]. 核农学报, 2023, 37(2):389-396.doi:10.11869/j.issn.1000-8551.2023.02.0389.
	Chen H, Li Y B, Shao Z Y, Zheng J R, Hu S S, Wang T L, Liu L H, Wang Q M. Effects of chitosan oligosaccharide and brassinosteroid treatments on yield and quality of tomato[J]. Journal of Nuclear Agricultural Sciences, 2023, 37(2):389-396. doi: 10.11869/j.issn.1000-8551.2023.02.0389
[5]	陈玉林, 倪琳琳, 周园园, 龚奕杰, 王珊, 冯均科, 唐静, 陈颖. 生物刺激素在设施番茄上的应用效果研究[J]. 上海蔬菜, 2022(1):51-55.doi:10.3969/j.issn.1002-1469.2022.01.021.
	Chen Y L, Ni L L, Zhou Y Y, Gong Y J, Wang S, Feng J K, Tang J, Chen Y. Study on the application effect of biostimulants on greenhouse tomatoes[J]. Shanghai Vegetables, 2022(1):51-55.
[6]	Bulgari R, Trivellini A, Ferrante A. Effects of two doses of organic extract-based biostimulant on greenhouse lettuce grown under increasing NaCl concentrations[J]. Frontiers in Plant Science, 2019, 9:1870.doi:10.3389/fpls.2018.01870. URL
[7]	du Jardin P. Plant biostimulants:definition,concept,main categories and regulation[J]. Scientia Horticulturae, 2015, 196:3-14.doi:10.1016/j.scienta.2015.09.021. URL
[8]	宋佳佳. 腐殖酸混合肥对温室黄瓜生长的影响[D]. 太谷: 山西农业大学, 2022.doi:10.27285/d.cnki.gsxnu.2022.000518.
	Song J J. Effect of humic acid mixed fertilizer on cucumber growth in greenhouse[D]. Taigu: Shanxi Agricultural University, 2022.
[9]	裴瑞杰, 王俊忠, 冀建华, 王志勇, 袁天佑, 孙笑梅, 闫军营. 腐殖酸肥料与氮肥配施对土壤理化性质的影响[J]. 江苏农业科学, 2018, 46(19):331-334.doi:10.15889/j.issn.1002-1302.2018.19.084.
	Pei R J, Wang J Z, Ji J H, Wang Z Y, Yuan T Y, Sun X M, Yan J Y. Effect of humic acid fertilizer combined with nitrogen fertilizer on soil physical and chemical properties[J]. Jiangsu Agricultural Sciences, 2018, 46(19):331-334.
[10]	刘增照. 腐殖酸肥在几种果树和作物应用效果的研究[D]. 杨凌: 西北农林科技大学, 2019.
	Liu Z Z. Study on application effect of humic acid fertilizer on several fruit trees and crops[D]. Yangling: Northwest A&F University, 2019.
[11]	Cheng P D, Yue Q Y, Zhang Y T, et al. Application of γ-aminobutyric acid(GABA)improves fruit quality and rootstock drought tolerance in apple[J]. Journal of Plant Physiology, 2023, 280:153890.doi:10.1016/j.jplph.2022.153890. URL
[12]	葛体达, 宋世威, 姜武, 唐东梅, 黄丹枫. 不同甘氨酸浓度对无菌水培番茄幼苗生长和氮代谢的影响[J]. 生态学报, 2009, 29(4):1994-2002.doi:10.3321/j.issn:1000-0933.2009.04.045.
	Ge T D, Song S W, Jiang W, Tang D M, Huang D F. Influence of glycine-N concentration on the growth and nitrogen metabolism of tomato seedlings under sterile hydroponics cultivation[J]. Acta Ecologica Sinica, 2009, 29(4):1994-2002.
[13]	鲁如坤. 土壤农业化学分析方法[M]. 北京: 中国农业科技出版社, 2000.
	Lu R K. Methods for agricultural chemical analysis of soil[M]. Beijing: China Agricultural Science and Technology Press, 2000.
[14]	郭傲, 林绪坚, 高欢欢, 郑雪莲, 陈默, 郑国华. 不同施钾水平对无花果糖积累及相关酶活性的影响[J]. 福建农业学报, 2019, 34(12):1388-1396.doi:10.19303/j.issn.1008-0384.2019.12.005.
	Guo A, Lin X J, Gao H H, Zheng X L, Chen M, Zheng G H. Effects of potassium fertilization on sugar metabolism and related enzymatic activities in ficus carica[J]. Fujian Journal of Agricultural Sciences, 2019, 34(12):1388-1396.
[15]	蔡庆生. 植物生理学实验[M]. 北京: 中国农业大学出版社, 2013:166-168.
	Cai Q S. Plant physiology experiment[M]. Beijing: China Agricultural University Press, 2013:166-168.
[16]	李合生. 植物生理生化实验原理和技术[M]. 北京: 高等教育出版社, 2000.
	Li H S. Experimental principles and techniques of plant physiology and biochemistry[M]. Beijing: Higher Education Press, 2000.
[17]	鲍士旦. 土壤农化分析[M]. 3版. 北京: 中国农业出版社, 2000.
	Bao S D. Soil agrochemical analysis.[M].3rd Ed.Beijing:China Agriculture Press,2000.
[18]	张治安. 植物生理学实验指导[M]. 北京: 中国农业科学技术出版社, 2004.
	Zhang Z A, Zhang M S, Wei R H. Guidance on plant physiology experiments[M]. Beijing: China Agricultural Science and Technology Press, 2004.
[19]	张爱华, 况胜剑, 张钦, 姚单君, 廖恒. 腐殖酸型复合肥对马铃薯生长及产质量的影响[J]. 耕作与栽培, 2021, 41(5):32-35.doi:10.3969/j.issn.1001-3601.2014.06.032.
	Zhang A H, Kuang S J, Zhang Q, Yao D J, Liao H. Effect of humic acid compound fertilizer on potato growth status,yield and quality[J]. Tillage and Cultivation, 2021, 41(5):32-35.
[20]	Elena A, Diane L, Eva B Y, Marta F, Roberto B, Zamarreño A M, García-Mina J M. The root application of a purified leonardite humic acid modifies the transcriptional regulation of the main physiological root responses to Fe deficiency in Fe-sufficient cucumber plants[J]. Plant Physiology and Biochemistry, 2009, 47(3):215-223.doi:10.1016/j.plaphy.2008.11.013. pmid: 19119016
[21]	徐全辉, 高仰, 赵强, 栗福州. 活性腐殖酸有机肥对水稻产量·养分吸收的影响[J]. 安微农业科学, 2010, 38(8):3951—3952.doi:10.3969/j.issn.1671-9212.2012.02.016.
	Xu Q H, Gao Y, Zhao Q, Li F Z. Effects of active humic acid organic fertilizer on yield and nutrientuptake of rice[J]. Journal of Anhui Agricultural Sciences, 2010, 38(8):3951-3952.
[22]	周爽, 倪志强, 张卫红, 谭钧, 邢文军, 李健鹏, 陈清. 腐植酸钾生产工艺及其在农业中的应用[J]. 腐植酸, 2016(6):9-15.doi:10.3969/j.issn.1671-9212.2016.06.004.
	Zhou S, Ni Z Q, Zhang W H, Tan J, Xing W J, Li J P, Chen Q. Potassium humate production process and its application in agriculture[J]. Humic Acid, 2016(6):9-15.
[23]	何建平, 陶启珍, 易平. 腐植酸液体叶面肥对马铃薯产量和品质的影响[J]. 腐植酸, 2004(1):24-26, 37.doi:10.3969/j.issn.1671-9212.2004.01.007.
	He J P, Tao Q Z, Yi P. Influence of liquid humic acid foliar fertilizer on yield and quality of potato[J]. Humic Acid, 2004(1):24-26,37.
[24]	范仲卿, 郭新送, 吴钦泉, 陈士更, 宋挚, 于晓东, 李巧玉, 王鹏, 丁方军, 马学文. 复合肥料中不同腐植酸质量分数对辣椒产量和品质的影响[J]. 山东科学, 2021, 34(4):60-66.doi:10.3976/j.issn.1002-4026.2021.04.010.
	Fan Z Q, Guo X S, Wu Q Q, Chen S G, Song Z, Yu X D, Li Q Y, Wang P, Ding F J, Ma X W. Effect of different mass fraction of humic acid in compound fertilizers on the yield and quality of chilli[J]. Shandong Science, 2021, 34(4):60-66.
[25]	梁满, 张昆, 沈一, 刘永惠, 沈悦, 张旭尧, 陈志德. 不同腐殖酸肥用量对花生生长发育和产量的影响[J]. 花生学报, 2022, 51(2):81-85.doi:10.14001/j.issn.1002-4093.2022.02.011.
	Liang M, Zhang K, Shen Y, Liu Y H, Shen Y, Zhang X Y, Chen Z D. Effect of different application rates of humic acid fertilizer on growth and yield of peanut[J]. Journal of Peanut Science, 2022, 51(2):81-85.
[26]	肖家昶, 雷凤芸, 格桑, 马俊英, 贺茂林, 李艳文, 郑阳霞. 外源喷施氨基酸肥对豆瓣菜生长与硒吸收的影响[J]. 浙江农业学报, 2023, 35(7):1638-1647.doi:10.3969/j.issn.1004-1524.20221184.
	Xiao J C, Lei F Y, Ge S, Ma J Y, He M L, Li Y W, Zheng Y X. Effects of exogenous spraying of amino acid fertilizer on growth and selenium uptake of watercress[J]. Zhejiang Journal of Agricultural Sciences, 2023, 35(7):1638-1647.
[27]	袁伟, 董元华, 王辉. 植物对氨基酸态氮吸收和利用的研究进展[J]. 中国土壤与肥料, 2009(4):4-9.doi:10.3969/j.issn.1673-6257.2009.04.002.
	Yuan W, Dong Y H, Wang H. Uptake and utilization of amino acid nitrogen by plants[J]. Soils and Fertilizers Sciences in China, 2009(4):4-9.
[28]	吴良欢, 陶勤南. 水稻氨基酸态氮营养效应及其机理研究[J]. 土壤学报, 2000, 37(4):464-473.doi:10.3321/j.issn:0564-3929.2000.04.005.
	Wu L H, Tao Q N. Effects of amino acid-N on rice nitrogen nutrition and its mechanism[J]. Acta Pedologica Sinica, 2000, 37(4):464-473.
[29]	王倩倩. 氨基酸类增效剂对蔬菜生长及土壤微生物的影响[D]. 银川: 宁夏大学, 2022.doi:10.27257/d.cnki.gnxhc.2022.000329.
	Wang Q Q. Effects of amino acid synergists on vegetable growth and soil microorganisms[D]. Yinchuan: Ningxia University, 2022.
[30]	钟晓红, 石雪晖, 肖浪涛. 色氨酸提高草莓果实品质和产量试验[J]. 中国果树, 2001, 1(2):4-7.doi:10.3969/j.issn.1000-8047.2001.02.002.
	Zhong X H, Shi X H, Xiao L T. Experiment on improving fruit quality and yield of strawberry by using tryptophane[J]. China Fruits, 2001, 1(2):4-7.

选择文件类型/文献管理软件名称

选择包含的内容