生物有机肥配合深松对农田土壤肥力和作物产量的影响

doi:10.13304/j.nykjdb.2022.0203

中国农业科技导报 ›› 2023, Vol. 25 ›› Issue (4): 157-166.DOI: 10.13304/j.nykjdb.2022.0203

• 生物制造资源生态 • 上一篇

生物有机肥配合深松对农田土壤肥力和作物产量的影响

可艳军¹(), 张雨萌²(), 郭艳杰²^,³, 张丽娟²^,³, 张子涛², 吉艳芝²^,³()

^1.河北省衡水市枣强县农业农村局，河北衡水 053199
^2.河北农业大学资源与环境科学学院，河北保定 071000
^3.河北农业大学河北省农田生态环境重点实验室，河北保定 071000

收稿日期:2022-03-27 接受日期:2022-06-27 出版日期:2023-04-01 发布日期:2023-06-26
通讯作者: 吉艳芝
作者简介:可艳军E-mail：349571289@qq.com
张雨萌E-mail： 954180401@ qq.com第一联系人：可艳军和张雨萌为共同第一作者。
基金资助:
国家重点研发计划(2017YFD0300905)

Effects of Bio-organic Fertilizer Combined with Subsoiling on Farmland Soil Fertility and Crop Yield

Yanjun KE¹(), Yumeng ZHANG²(), Yanjie GUO²^,³, Lijuan ZHANG²^,³, Zitao ZHANG², Yanzhi JI²^,³()

^1.Agricultural and Rural Bureau of Zaoqiang County，Hengshui City，Hebei Province，Hebei Hengshui 053199，China
^2.College of Resources and Environmental Sciences，Hebei Agricultural University，Hebei Baoding 071000，China
^3.Key Laboratory for Farmland Eco-environment of Hebei Province，Hebei Agricultural University，Hebei Baoding 071000，China

Received:2022-03-27 Accepted:2022-06-27 Online:2023-04-01 Published:2023-06-26
Contact: Yanzhi JI

摘要/Abstract

摘要：

为研究生物有机肥配合深松对农田土壤肥力和作物产量的影响，采用田间裂区设计，冬小麦季设置生物有机肥替代化肥氮0%（M0）、10%（M1）、20%（M2）3个主区，夏玉米季设置传统耕作（P）和深松耕作（S）2个副区，分析不同处理下土壤理化性状、微生物量与作物产量等。2年的试验结果表明，与传统（M0P）相比，生物有机肥替代化肥氮10%、20%配合深松的土壤容重分别降低8.03%和6.57%，水稳性大团聚体含量提高46.12%和28.01%；pH由8.17降到7.94和8.00；土壤有机质、硝态氮、有效磷和速效钾含量随生物有机肥替代量的增加而增加，深松耕作对土壤养分提升效果不显著；土壤微生物量碳、氮量在小麦季分别增加15.77%和17.28%，夏玉米季分别提高66.49%和55.30%；作物总产量分别达到39 256 和36 618 kg·hm^-2，较对照处理分别增加13.20%和10.46%。综上所述，冬小麦季采用生物有机肥替代化肥氮10%~20%配合夏玉米季深松播种，能改善土壤理化性状，增加微生物量，提高作物产量，可作为改良华北平原农田土壤肥力提升的有效措施。

关键词: 生物有机肥, 深松, 土壤肥力, 产量, 小麦-玉米轮作

Abstract:

To study the effects of bio-organic fertilizer with deep loosening on soil fertility and crop yield， a field split-zone design was used， with three main zones of 0% （M0）， 10% （M1） and 20% （M2） of bio-organic fertilizer replacing chemical fertilizer N in winter wheat season， and two sub-zones of conventional tillage （P） and deep loosening tillage （S） in summer corn season， the soil physical and chemical properties， microbial load and crop yield were analyzed under different treatments. The results of the 2 years experiment showed that compared with conventional （M0P）， the soil capacity of bio-organic fertilizer replacing 10% and 20% of chemical fertilizer N with deep tillage decreased by 8.03% and 6.57%， respectively， and the content of water-stable macromolecules increased by 46.12% and 28.01%； pH decreased from 8.17 to 7.94 and 8.00. The soil organic matter， nitrate nitrogen， effective phosphorus and fast-acting potassium contents increased with the increase of bio-organic fertilizer replacement， and the effect of deep tillage on soil nutrient enhancement was not significant. Soil microbial carbon and nitrogen increased by 15.77% and 17.28% in wheat season and 66.49% and 55.30% in summer maize season， respectively； total crop yield reached 39 256 and 36 618 kg·hm^-2， increasing by 13.20% and 10.46% compared with the control treatment， respectively. In conclusion， the use of bio-organic fertilizer to replace 10%~20% of chemical fertilizer N in the winter wheat season in combination with the deep pine sowing in the summer maize season could improve the soil physicochemical properties， increase the microbial load and improve the crop yield， which could be used as an effective measure to improve the soil fertility enhancement of farmland in the North China Plain.

Key words: biological organic fertilizer, subsoiling, soil fertility, yield, wheat-corn rotation

中图分类号:

S158.5

可艳军, 张雨萌, 郭艳杰, 张丽娟, 张子涛, 吉艳芝. 生物有机肥配合深松对农田土壤肥力和作物产量的影响[J]. 中国农业科技导报, 2023, 25(4): 157-166.

Yanjun KE, Yumeng ZHANG, Yanjie GUO, Lijuan ZHANG, Zitao ZHANG, Yanzhi JI. Effects of Bio-organic Fertilizer Combined with Subsoiling on Farmland Soil Fertility and Crop Yield[J]. Journal of Agricultural Science and Technology, 2023, 25(4): 157-166.

图/表 8

参考文献 30

1	巨晓棠,张翀.论合理施氮的原则和指标[J].土壤学报,2021,58(1):1-13.
	JU X T, ZHANG C. The principles and indicators of rational N fertilization [J]. Acta Pedol. Sin., 2021, 58(1): 1-13.
2	张恒恒,严昌荣,张燕卿,等.北方旱区免耕对农田生态系统固碳与碳平衡的影响[J].农业工程学报,2015,31(4):240-247.
	ZHANG H H, YAN C R, ZHANG Y Q, et al.. Effect of no tillage on carbon sequestration and carbon balance in farming ecosystem in dryland area of northern China [J]. Trans. Chin. Soc. Agric. Eng., 2015, 31(4): 240-247.
3	闫百莹.深松结合施用有机肥料对玉米产量与养分吸收的影响[D].大庆:黑龙江八一农垦大学,2020.
	YAN B Y. Effects of combined application of organic fertilizers with subsoiling on maize yield and nutrient absorption [D]. Daqing: Heilongjiang Bayi Agricultural University, 2020.
4	GEZAHEGN A M. Effect of organic fertilizers on maize (Zea mays L.) production and soil physical and chemical properties [J]. World Appl. Sci. J., 2021, 39(1): 11-19.
5	SHAHINUR N N, AMIN A, BISWAS P K, et al.. Feasibility of replacing chemical fertilizer by organic fertilizer in maize (Zea mays L.) production in dhaka, bangladesh [J/OL]. Int. J. Plant Soil Sci., 2019,30(3): 330177 [2022-02-17]. .
6	季佳鹏,赵欣宇,吴景贵,等.有机肥替代20%化肥提高黑钙土养分有效性及玉米产量[J]. 植物营养与肥料学报,2021,27(3):491-499.
	JI J P, ZHAO X Y, WU J G, et al.. Replacing 20% of chemical nitrogen with manures to increase soil nutrient availability and maize yield in a chernozem soil [J]. J. Plant Nutr. Fert., 2021, 27(3): 491-499.
7	ZHANG Y J, WANG R, WANG A L, et al.. Effects of different sub-soiling frequencies incorporated into no-tillage systems on soil properties and crop yield in dryland wheat-maize rotation system [J]. Field Crops Res., 2017, 209: 151-158.
8	SHEN Y, ZHANG T T, CUI J C, et al.. Subsoiling increases aggregate-associated organic carbon, dry matter, and maize yield on the North China Plain [J/OL]. J. Peer, 2021, 9: e11099[2022-02-17]. .
9	赵亚丽,刘卫玲,程思贤,等.深松(耕)方式对砂姜黑土耕层特性、作物产量和水分利用效率的影响[J].中国农业科学,2018,51(13):2489-2503.
	ZHAO Y L, LIU W L, CHENG S X, et al.. Effects of pattern of deep tillage on topsoil features, yield and water use efficiency in lime concretion black soil [J]. Sci. Agric. Sin., 2018, 51(13): 2489-2503.
10	张久明,迟凤琴,宿庆瑞,等.不同有机物料还田对土壤结构与玉米光合速率的影响[J].农业资源与环境学报,2014,31(1):56-61.
	ZHANG J M, CHI F Q, SU Q R, et al.. Effect of different organic material turnover on soil structure and maize photosynthetic rate [J]. J. Agric. Resour. Environ., 2014, 31(1): 56-61.
11	李娟,葛磊,曹婷婷,等.有机肥施用量和耕作方式对旱地土壤水分利用效率及作物生产力的影响[J].水土保持学报,2019,33(2):121-127.
	LI J, GE L, CAO T T, et al.. Effects of organic fertilization and tillage on soil water use efficiency and crop yield in dryland [J]. J. Soil Water Conserv., 2019, 33(2): 121-127.
12	JAKOBS I, SCHMITTMANN O, ATHMANN M, et al.. Cereal response to deep tillage and incorporated organic fertilizer [J]. Agronomie, 2019, 9(6): 1-16.
13	吕贻忠,李保国.土壤学实验[M].北京:中国农业出版社,2010:44-136.
14	鲍士旦.土壤农化分析[M].北京:中国农业出版社,2000:30-108.
15	张琳,孙卓玲,马理,等.不同水氮条件下双氰胺(DCD)对温室黄瓜土壤氮素损失的影响[J].植物营养与肥料学报,2015,21(1):128-137.
	ZHANG L, SUN Z L, MA L, et al.. Effects of dicyandiamide on nitrogen loss from cucumber planting soil in intensive greenhouse under different irrigation and nitrogen conditions [J]. J. Plant Nutr. Fert., 2015, 21(1): 128-137.
16	林先贵.土壤微生物研究原理与方法[M].北京:高等教育出版社,2010:73-76.
	LIN X G. Principles and Mmethods of Soil Microbial Rresearch [M]. Beijing: Higher Education Press, 2010:73-76.
17	谢钧宇, 曹寒冰, 孟会生, 等.不同施肥措施及施肥年限下土壤团聚体的大小分布及其稳定性[J].水土保持学报,2020,34(3):274-281.
	XIE J Y, CAO H B, MENG H S, et al..Effects of different fertilization regimes and fertilization on ages on size distribution and stability of soil aggregates [J]. J. Soil Water Conserv., 2020,34(3):274-281.
18	刘明月,张凯鸣,毛伟,等.有机肥长期等氮替代无机肥对稻麦产量及土壤肥力的影响[J].华北农学报,2021,36(3):133-141.
	LIU M Y, ZHANG K M, MAO W, et al.. Effects of long-term substitution of inorganic fertilizers with organic fertilizers on rice and wheat yields and soil fertility [J]. Acta Agric. Boreali-Sin., 2021, 36(3): 133-141.
19	ZHENG W, ZENG S, BAIS H, et al.. Plant growth-promoting rhizoma bacteria (PGPR) reduce evaporation and increase soil water retention [J]. Water Resour. Res., 2018, 54(5): 3673-3687.
20	刘帅,赵西宁,李钊,等.不同改良剂对旱地苹果园壤土团聚体和水分的影响[J].水土保持学报,2021,35(2):193-199.
	LIU S, ZHAO X N, LI Z, et al.. Effects of different amendments on aggregate and water content of loam soil in dryland apple orchard [J]. J. Soil Water Conserv., 2021, 35(2): 193-199.
21	李俊,姜昕,马鸣超,等.新形势下微生物肥料产业运行状况及发展方向[J].植物营养与肥料学报,2020,26(12):2108-2114.
	LI J, JIANG X, MA M C, et al.. Situation and development direction for microbial fertilizer industry in the near future of China [J]. J. Plant Nutr. Fert., 2020, 26(12): 2108-2114.
22	张世卿.小麦-玉米轮作系统中生物有机肥替代不同比例化肥的效应研究[D].保定:河北农业大学,2020.
	ZHANG S Q. Effect of bio-organic fertilizer replacing different proportion of chemical fertilizer in wheat and maize rotation system [D]. Baoding: Hebei Agriculture University, 2020.
23	于晓芳,赵晓宇,胡树平,等.内蒙古河套平原灌区玉米适宜耕作方式研究[J].植物营养与肥料学报,2019,25(3):392-401.
	YU X F, ZHAO X Y, HU S P, et al.. Tillage method suitable for farmlands with different maize yield levels in Hetao plain, Inner Mongolia [J]. J. Plant Nutr. Fert., 2019, 25(3): 392-401.
24	于海磊,吴息,吴云龙,等.气候变化背景下深松播种对玉米农田土壤水热与呼吸特性的影响[J].玉米科学,2019,27(2):99-105.
	YU H L, WU X, WU Y L, et al.. Effects of deep tillage on the characteristics of soil and grain yield in summer maize field [J]. J. Maize Sci., 2019, 27(2): 99-105.
25	ZHOU J, JIANG X, ZHOU B, et al.. Thirty four years of nitrogen fertilization decreases fungal diversity and alters fungal community composition in black soil in northeast China [J]. Soil Biol. Biochem., 2016, 95: 135-143.
26	ZHAO J, NI T, LI J, et al.. Effects of organk-inorganic compound fertilizer with reduced chemical fertilizer application on cropping system [J]. Appl. Soil Ecol., 2016, 99: 1-12.
27	曲成闯,陈效民,韩召强,等.生物有机肥对潮土物理性状及微生物量碳、氮的影响[J].水土保持通报,2018,38(5):70-76.
	QU C C, CHEN X M, HAN Z Q, et al.. Effects of bioorganic fertilizer application on soil physical properties and microbial biomass carbon and nitrogen in fluvoaquic soil [J]. Bull. Soil Water Conserv.,2018, 38(5): 70-76.
28	CHEN C, ZHANG J, LU M, et al.. Microbial communities of an arable soil treated for 8 years with organic and inorganic fertilize [J]. Biol. Fert. Soils, 2016, 52(4): 455-467.
29	FTRATN B N, AMANDA A P, KAMALUDDN N N, et al.. Some soil biological and chemical properties as affected by biofertilizers and organic ameliorants application on paddy rice [J]. Eurasian J. Soil Sci., 2021, 10(2): 105-110.
30	DODD I C, ZINOVKINA N Y, SAFRONOVA V I, et al.. Rhizobacterial mediation of plant hormone status [J]. Ann. Appl. Biol., 2010, 157(3): 361-379.

处理 Treatment	2017—2018		2018—2019
处理 Treatment	冬小麦 Winter wheat	夏玉米 Summer corn	冬小麦 Winter wheat	夏玉米 Summer corn
M0P	1.37 a	1.46 a	1.31 a	1.37 a
M1P	1.33 a	1.40 ab	1.27 a	1.31 ab
M2P	1.28 b	1.43 ab	1.24 ab	1.30 b
M0S	—	1.39 ab	1.25 ab	1.29 b
M1S	—	1.34 b	1.19 b	1.28 b
M2S	—	1.35 b	1.18 b	1.27 b

处理 Treatment	2017—2018		2018—2019
处理 Treatment	冬小麦 Winter wheat	夏玉米 Summer corn	冬小麦 Winter wheat	夏玉米 Summer corn
M0P	1.37 a	1.46 a	1.31 a	1.37 a
M1P	1.33 a	1.40 ab	1.27 a	1.31 ab
M2P	1.28 b	1.43 ab	1.24 ab	1.30 b
M0S	—	1.39 ab	1.25 ab	1.29 b
M1S	—	1.34 b	1.19 b	1.28 b
M2S	—	1.35 b	1.18 b	1.27 b

作物 Crop	处理 Treatment	各粒级含量比例 Particle size content proportion/%							平均重量直径MWD/mm	几何平均直径GMD/mm
作物 Crop	处理 Treatment	<0.25	0.25~0.5	0.5~1	1~2	2~5	>5	R_0.25	平均重量直径MWD/mm	几何平均直径GMD/mm
冬小麦 Winter wheat	M0P	71.84 ab	12.96 c	8.58 ab	3.34 a	2.96 a	0.32 c	28.16 cd	0.26 c	0.20 b
	M1P	67.69 bc	16.96 bc	10.40 ab	2.42 a	1.41 b	1.12 b	32.31 bc	0.30 b	0.21 ab
	M2P	59.82 c	18.93 ab	12.23 a	4.91 a	2.33 ab	1.78 b	40.18 a	0.43 ab	0.25 a
	M0S	76.50 a	10.30 c	5.85 b	2.64 a	2.29 ab	2.42 ab	23.50 d	0.36 ab	0.20 b
	M1S	62.75 c	19.30 a	9.10 ab	3.30 a	2.72 ab	2.83 ab	37.25 ab	0.47 ab	0.24 a
	M2S	62.65 c	17.48 ab	9.96 ab	3.39 a	2.84 a	3.69 a	37.35 ab	0.54 a	0.25 a
夏玉米 Summer corn	M0P	76.26 a	6.05 a	5.16 a	3.89 b	4.36 a	4.28 a	23.74 b	0.55 b	0.22 b
	M1P	71.77 ab	7.24 a	6.80 a	5.14 ab	4.54 a	4.51 a	28.23 ab	0.61 ab	0.24 ab
	M2P	67.95 b	7.59 a	7.28 a	6.66 ab	5.57 a	4.95 a	32.05 ab	0.69 a	0.27 ab
	M0S	73.90 ab	6.36 a	5.72 a	4.38 b	4.96 a	4.68 a	26.10 b	0.61 ab	0.23 ab
	M1S	69.61 ab	7.52 a	6.95 a	6.10 ab	5.04 a	4.78 a	30.39 ab	0.66 ab	0.26 ab
	M2S	65.31 b	8.28 a	7.67 a	7.02 a	6.68 a	5.04 a	34.69 a	0.74 a	0.28 a

作物 Crop	处理 Treatment	各粒级含量比例 Particle size content proportion/%							平均重量直径MWD/mm	几何平均直径GMD/mm
作物 Crop	处理 Treatment	<0.25	0.25~0.5	0.5~1	1~2	2~5	>5	R_0.25	平均重量直径MWD/mm	几何平均直径GMD/mm
冬小麦 Winter wheat	M0P	71.84 ab	12.96 c	8.58 ab	3.34 a	2.96 a	0.32 c	28.16 cd	0.26 c	0.20 b
	M1P	67.69 bc	16.96 bc	10.40 ab	2.42 a	1.41 b	1.12 b	32.31 bc	0.30 b	0.21 ab
	M2P	59.82 c	18.93 ab	12.23 a	4.91 a	2.33 ab	1.78 b	40.18 a	0.43 ab	0.25 a
	M0S	76.50 a	10.30 c	5.85 b	2.64 a	2.29 ab	2.42 ab	23.50 d	0.36 ab	0.20 b
	M1S	62.75 c	19.30 a	9.10 ab	3.30 a	2.72 ab	2.83 ab	37.25 ab	0.47 ab	0.24 a
	M2S	62.65 c	17.48 ab	9.96 ab	3.39 a	2.84 a	3.69 a	37.35 ab	0.54 a	0.25 a
夏玉米 Summer corn	M0P	76.26 a	6.05 a	5.16 a	3.89 b	4.36 a	4.28 a	23.74 b	0.55 b	0.22 b
	M1P	71.77 ab	7.24 a	6.80 a	5.14 ab	4.54 a	4.51 a	28.23 ab	0.61 ab	0.24 ab
	M2P	67.95 b	7.59 a	7.28 a	6.66 ab	5.57 a	4.95 a	32.05 ab	0.69 a	0.27 ab
	M0S	73.90 ab	6.36 a	5.72 a	4.38 b	4.96 a	4.68 a	26.10 b	0.61 ab	0.23 ab
	M1S	69.61 ab	7.52 a	6.95 a	6.10 ab	5.04 a	4.78 a	30.39 ab	0.66 ab	0.26 ab
	M2S	65.31 b	8.28 a	7.67 a	7.02 a	6.68 a	5.04 a	34.69 a	0.74 a	0.28 a

养分 Nutrient	处理 Treatment	2017—2018		2018—2019
养分 Nutrient	处理 Treatment	冬小麦 Winter wheat	夏玉米 Summer corn	冬小麦 Winter wheat	夏玉米 Summer corn
硝态氮 Nitrate nitrogen/ （mg·kg^-1）	M0P	4.07 b	4.26 d	5.18 bc	6.72 b
	M1P	6.13 ab	8.80 bc	5.06 bc	7.76 b
	M2P	7.80 a	11.47 ab	10.90 a	7.77 b
	M0S	—	6.69 cd	2.69 c	8.34 ab
	M1S	—	12.05 ab	5.05 bc	10.83 a
	M2S	—	13.48 a	6.52 b	6.68 b
有效磷 Available phosphorus/ （mg·kg^-1）	M0P	18.81 b	11.09 c	23.83 c	20.81 bc
	M1P	24.88 a	17.95 b	25.33 bc	26.52 a
	M2P	25.12 a	12.00 c	24.98 bc	24.22 ab
	M0S	—	18.04 b	28.79 bc	10.99 e
	M1S	—	22.68 a	31.79 b	19.10 cd
	M2S	—	17.92 b	44.26 a	14.32 de
速效钾 Available potassium/ （mg·kg^-1）	M0P	226.63 b	265.32 a	352.95 b	265.75 b
	M1P	273.33 a	239.33 ab	412.10 a	375.45 a
	M2P	282.93 a	225.23 b	377.23 b	294.20 b
	M0S	—	189.07 c	357.55 b	278.30 b
	M1S	—	248.18 ab	379.05 b	357.55 a
	M2S	—	270.33 a	360.77 b	275.80 b

生物有机肥配合深松对农田土壤肥力和作物产量的影响

Effects of Bio-organic Fertilizer Combined with Subsoiling on Farmland Soil Fertility and Crop Yield

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

图/表 8

参考文献 30

相关文章 15

编辑推荐

Metrics

处理 Treatment	冬小麦Winter wheat		夏玉米Summer corn
处理 Treatment	微生物量碳 MBC	微生物量氮 MBN	微生物量碳 MBC	微生物量氮 MBN
M0P	355.84 b	15.62 b	212.65 c	49.51 c
M1P	367.95 ab	16.49 ab	250.93 bc	58.79 bc
M2P	386.11 ab	16.87 ab	308.23 ab	66.08 ab
M0S	370.75 ab	16.09 ab	240.67 bc	54.79 bc
M1S	381.44 ab	17.27 ab	307.26 ab	60.40 ab
M2S	411.94 a	18.32 a	354.05 a	78.87 a

年份 Year	作物 Crop	处理 Treatment
年份 Year	作物 Crop	M0P	M1P	M2P	M0S	M1S	M2S
2017—2018	冬小麦 Winter wheat	6 973 a	7 208 a	7 300 a	—	—	—
2017—2018	夏玉米 Summer corn	10 882 a	12 238 a	12 809 a	11 855 a	11 822 a	12 911 a
2018—2019	冬小麦 Winter wheat	6 600 b	6 767 b	7 350 a	6 700 b	7 000 ab	7 367 a
2018—2019	夏玉米 Summer corn	8 696 b	10 425 ab	10 069 ab	9 763 ab	10 588 ab	11 678 a
合计 Total		33 151 c	36 638 ab	37 528 ab	35 291 bc	36 618 ab	39 256 a

[1]	杨玲, 张富仓, 孙鑫, 张少辉, 王海东, ABDELGHANY Ahmed Elsayed, 陈占飞, 方玉川. 生物炭和滴灌量对陕北榆林沙土性质和马铃薯生长的影响[J]. 中国农业科技导报, 2023, 25(3): 221-233.
[2]	郑云珠, 孙树臣. 秸秆生物炭和秸秆对麦玉轮作系统土壤养分及作物产量的影响[J]. 中国农业科技导报, 2023, 25(2): 152-162.
[3]	黄巧义, 吴永沛, 黄旭, 李苹, 付弘婷, 张木, 逄玉万, 曾招兵, 唐拴虎. 控释尿素与尿素配施对甜玉米产量和氮肥利用率的影响[J]. 中国农业科技导报, 2023, 25(2): 163-173.
[4]	郭巨先, 欧阳碧珊, 李桂花, 符梅, 罗文龙, 骆善伟, 陆美莲. 微生物有机肥对连作菜薹生长及土壤性质的影响[J]. 中国农业科技导报, 2023, 25(2): 182-191.
[5]	董伟欣, 李东晓, 张月辰. 不同氮素水平对夏玉米生理参数及产量品质的影响[J]. 中国农业科技导报, 2023, 25(1): 142-152.
[6]	向开宏, 吕旭, 舒川海, 伍杂日曲, 张金悦, 朱岳梅, 杨志远, 孙永健, 马均. 有机无机肥配施对精量穴直播水稻产量及氮素利用的影响[J]. 中国农业科技导报, 2022, 24(9): 149-165.
[7]	项洪涛, 李琬, 何宁, 王强, 曾玲玲, 王曼力, 杨纯杰, 冯延江. 小豆根系对水分胁迫的生理响应及S3307的缓解效应[J]. 中国农业科技导报, 2022, 24(9): 39-49.
[8]	陈元伟, 郑华斌, 王慰亲, 旷娜, 罗友谊, 邹丹, 唐启源. 刈割处理对再生稻头季全株生物量、青贮品质和再生季产量的影响[J]. 中国农业科技导报, 2022, 24(8): 161-171.
[9]	魏全全, 高英, 芶久兰, 张萌, 饶勇, 杨斌, 凡迪, 冯文豪, 肖华贵. 播种量和播种方式对冬油菜养分吸收利用及产量的影响[J]. 中国农业科技导报, 2022, 24(8): 182-191.
[10]	刘雪静, 鲍晓远, 候晓阳, 甄文超. 海河平原春季限水灌溉下冬小麦农田水分动态及产量形成特征[J]. 中国农业科技导报, 2022, 24(7): 167-176.
[11]	彭增莹, 申莹莹, 段松江, 吴一帆, 李宗润, 郭仁松, 张巨松. 化学调控对不同施氮量棉花冠层结构及产量的影响[J]. 中国农业科技导报, 2022, 24(7): 177-186.
[12]	白思琦, 邹晓荣, 丁鹏, 林铭. 基于环境因子的东南太平洋智利竹筴鱼剩余产量模型建立[J]. 中国农业科技导报, 2022, 24(7): 197-204.
[13]	党翼, 张建军, 赵刚, 樊廷录, 王磊, 李尚中, 周刚. 控释尿素和普通尿素配施对旱地玉米产量和水氮利用效率的影响[J]. 中国农业科技导报, 2022, 24(6): 156-165.
[14]	高桐梅, 李丰, 苏小雨, 王东勇, 田媛, 张鹏钰, 李同科, 杨自豪, 卫双玲. 减施氮肥对芝麻农艺性状、光合特性及产量的影响[J]. 中国农业科技导报, 2022, 24(6): 176-188.
[15]	赵晨光, 牛司耘, 陈勋, 方丽, 李海涛, 王佩星, 沈镔镔, 石元值. 复合肥料对茶叶产量、品质及茶园土壤肥力的影响[J]. 中国农业科技导报, 2022, 24(6): 206-217.