Effect of Graphene on Soil Nutrient Transformation and Root Growth of Maize Seedlings

doi:10.13304/j.nykjdb.2022.0500

Abstract

Abstract:

Graphene is now widely used in agricultural production because of its unique structure and excellent properties. To investigate the effects of graphene on soil nutrients， enzyme activities and maize root development， the pot experiment using ‘Zhengdan 958’ as the test material was carried out to examine the effects of single-layer graphene （TS） and few-layer graphene （TF） at 0 （CK）， 25， 50， 100 and 150 g·kg^-1 on the transformation of soil nutrients and the root development of maize seedlings， respectively. The results showed that， compared with the control （CK）， the soil available nutrient content increased significantly with the increase of graphene concentration and reached the maximum at the concentration of 150 g·kg^-1， in which， the available nitrogen， available phosphorus and available potassium of single-layer graphene treatment significantly increased by 21.85%， 76.56% and 30.69%， and those of few-layer graphene treatment significantly increased by 23.05%， 82.16% and 47.20%， respectively. Meanwhile， the addition of graphene also contributed to the increase of soil enzyme activity， but the soil enzyme activity showed a trend of increasing firstly and then decreasing with increasing concentration， and the sucrase and urease activities of few-layer of graphene at a concentration of 50 g·kg^-1 significantly increased by 6.67% and 21.26% compared to CK. Low levels （25， 50， and 100 g·kg^-1） promoted inhibition at high level （150 g·kg^-1）. Low levels of graphene inhibited the rate of superoxide anion （ $O 2 · -$ ） production and the accumulation of malondialdehyde （MDA）， and increased the contents of soluble protein and proline， which helped to timely scavenge reactive oxygen species， inhibit membrane lipid synthesis， lessen the harm done to the root system. In conclusion， the applied properly graphene could enhance soil nutrients， boost soil enzyme activity， and encourage the development of maize plants. And the effect of few-layer graphene was better than that of the single-layer graphene.

Key words: graphene, maize, root, soil nutrient, enzyme activity

摘要：

石墨烯因具有独特结构及优异性能，在农业生产中被广泛应用。为探究石墨烯对土壤养分、酶活性及玉米根系发育的影响，以‘郑单958’为试材，进行盆栽试验，研究单层石墨烯（TS）和少层石墨烯（TF）分别在0（CK）、25、50、100和150 g·kg^-1用量时对土壤养分转化及玉米苗期根系生长的影响。结果表明，与对照（CK）相比，随石墨烯施用量的增加，土壤速效养分含量呈显著增加趋势，在施用量为150 g·kg^-1时达最大值，其中，单层石墨烯处理的碱解氮、有效磷和速效钾含量较CK分别显著增加21.85%、76.56%和30.69%；少层石墨烯处理较CK分别显著增加23.05%、82.16%和47.20%。同时，添加石墨烯还有助于土壤酶活性的提高，但随施用量的增加，土壤酶活性呈先升高后降低趋势，少层石墨烯处理在施用量为50 g·kg^-1时土壤蔗糖酶和脲酶活性较CK分别显著增加6.67%和21.26%。单层和少层石墨烯处理均有利于增加植株干重和鲜重，但对根长增加效果不显著。根系中抗氧化酶活性和非酶抗氧化剂含量表现为低水平（25、50和100 g·kg^-1）促进高水平（150 g·kg^-1）抑制，且低水平时抑制了超氧阴离子（superoxide anion production rate， $O 2 · -$ ）的产生速率和丙二醛（malonaldehyde，MDA）的积累，增加了可溶性蛋白和脯氨酸的含量，有助于及时清除活性氧，减轻对根系造成的损伤。综上，合理施用石墨烯可改善土壤养分、提高土壤酶活性、促进玉米植株生长，且少层石墨烯处理的效果优于单层石墨烯处理。

关键词: 石墨烯, 玉米, 根系, 土壤养分, 酶活性

CLC Number:

S513

Shiya WANG, Xinyi WANG, Ying LIU, Huiying HU, Haiyan SUN, Wei GUO. Effect of Graphene on Soil Nutrient Transformation and Root Growth of Maize Seedlings[J]. Journal of Agricultural Science and Technology, 2023, 25(11): 192-206.

王诗雅, 王欣怡, 刘莹, 胡慧颖, 孙海燕, 郭伟. 石墨烯对土壤养分转化及玉米苗期根系生长的影响[J]. 中国农业科技导报, 2023, 25(11): 192-206.

Figures/Tables 9

Fig. 1 Contents of available nutrients under soil under different treatmentsNote：Different lowercase letters indicate significant differences between different treatments at P<0.05 level.

Fig. 2 Soil enzyme activity under different treatmentsNote：Different lowercase letters indicate significant differences between different treatments at P<0.05 level.

Table 1 Fresh weight， dry weight and root length of maize root under different treatments

处理Treatment	根长 Root length/cm	根鲜重 Root fresh weight/g	根干重 Root dry weight/g	根体积 Root volume/cm³	地上部鲜重 Shoot fresh weight/g	地上部干重 Shoot dry weight/g
CK	41.33±0.67 b	4.63±0.13 c	0.84±0.02 d	6.83±0.75 c	4.40±0.29 c	0.58±0.03 c
TS1	41.43±1.06 b	5.38±0.07 b	1.11±0.05 b	8.23±0.49 b	5.57±0.30 b	0.73±0.11 b
TS2	44.07±0.67 a	5.86±0.08 a	1.33±0.03 a	9.67±0.60 a	7.58±0.77 a	0.86±0.02 a
TS3	42.73±0.55 ab	5.20±0.07 b	0.96±0.03 c	8.20±0.62 b	4.67±0.15 c	0.57±0.06 c
TS4	37.27±0.64 c	4.63±0.03 c	0.87±0.02 cd	6.87±0.35 c	4.35±0.21 c	0.59±0.03 c
TF1	43.20±0.97 ab	5.23±0.12 d	0.88±0.01 bc	7.07±0.15 bc	5.56±0.35 b	0.77±0.17 bc
TF2	44.97±1.07 a	6.19±0.04 b	1.12±0.08 a	8.13±0.21 a	5.67±0.35 b	0.92±0.17 ab
TF3	43.77±1.30 ab	6.59±0.03 a	1.19±0.06 a	8.60±0.40 a	6.95±0.27 a	1.09±0.15 a
TF4	42.68±0.65 b	5.68±0.08 c	0.97±0.04 b	7.87±0.65 ab	5.66±0.22 b	0.81±0.04 bc

Fig. 3 Root O2·- production rates under different treatmentsNote：Different lowercase letters indicate significant differences between different treatments at P<0.05 level.

Fig. 4 MDA content of roots under different treatmentsNote：Different lowercase letters indicate significant differences between different treatments at P<0.05 level.

Fig. 5 Antioxidant enzyme activities of roots under different treatmentsNote：Different lowercase letters indicate significant differences between different treatments at P<0.05 level.

Fig. 6 Non-enzymatic antioxidant content of roots under different treatmentsNote：Different lowercase letters indicate significant differences between different treatments at P<0.05 level.

Fig. 7 Carbohydrate content of roots under different treatmentsNote：Different lowercase letters indicate significant differences between different treatments at P<0.05 level.

Fig. 8 Correlation analysis among the indicators of graphene treatmentsNote：* and ** indicate significant correlations at P<0.05 and P<0.01 levels， respectively.

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[3]	Caiyan DU, Haiyan LU, Yanzhu XIONG, Xi SUN, Xiumei SUN, Jixiong PU, Naiming ZHANG. Effects of Combined Application of Biogas Slurry and Chemical Fertilizer on Peach Growth and Soil Physical and Chemical Properties for Two Consecutive Years [J]. Journal of Agricultural Science and Technology, 2023, 25(8): 165-175.
[4]	Rui XIAO, Lu TAN, Liang WU, Hao ZHANG, Jiayuan GUO, Haijun YANG. Microbial Community Structure and Diversity in Rhizosphere and Non-rhizosphere Soil of Kochia scoparia Under Cd Stress [J]. Journal of Agricultural Science and Technology, 2023, 25(8): 203-215.
[5]	Shijian BAI, Jinge HU, Jiuyun WU, Wen ZHANG, Hui XIE, Ronghua ZHAO, Guang CHEN, Junshe CAI. Effects of Rootstocks on the Growth Characteristics and Fruit Quality of ‘Crimson Seedless’ Grapes in Turpan Region [J]. Journal of Agricultural Science and Technology, 2023, 25(8): 76-87.
[6]	Xiang WU, Juan LI, Yan CAO, Yanrong CHENG, Xuyu YAN, Ling LI. Research Advances on Plant Root Exudates in Response to Cadmium Stress [J]. Journal of Agricultural Science and Technology, 2023, 25(7): 12-20.
[7]	Xingsheng YIN, Lingfeng BAO, Yongyu PU, Jiali SUN, Qing ZHANG, Haiping LI, Mingying YANG, Yueping LIN, Huaixin WANG, Yonghong HE, Peiwen YANG. Effects of Chemical Fertilizer Reduction Combined with Bio-organic Fertilization on Tobacco Soil Characteristics and Tobacco Bacterial Wilt Control [J]. Journal of Agricultural Science and Technology, 2023, 25(7): 122-131.
[8]	Yaxuan MENG, Wei MA, Xuhang YAO, Yingqi SUN, Xin ZHONG, Shan HUANG, Qiaoyun WENG, Yinghui LIU, Jincheng YUAN. Study on the Response Factors of Maize Yield to Nitrogen Fertilizer [J]. Journal of Agricultural Science and Technology, 2023, 25(7): 153-160.
[9]	Yajun YUAN, Jiaxing FENG, Qifan YANG, Xue BAI, R A J PUSHPA, Dahong BIAN, Yanhong CUI. Lodging-resistance Comparison Among Sumer Maize Varieties with Different Growth Period in North of Huang-Huai-Hai Plain [J]. Journal of Agricultural Science and Technology, 2023, 25(7): 21-28.
[10]	Panpan ZHANG, Chuan LI, Meiwei ZHANG, Xia ZHAO, Jun NIU, Jiangfang QIAO. Effect of Nitrification Inhibitor Application on Nitrogen Accumulation and Transportation and Grain Yield of Summer Maize Under Reduced Nitrogen [J]. Journal of Agricultural Science and Technology, 2023, 25(6): 181-189.
[11]	Hongyuan LIU, Zhihua ZHOU, Guangxin ZHAO, Yanjun WANG, Nana WANG. Effects of Modified Cellulose on Germination and Dryland Soil Physicochemical Properties of Upland Rice [J]. Journal of Agricultural Science and Technology, 2023, 25(5): 168-175.
[12]	Yinan JIA, Guangdi ZHANG, Haoyu ZHANG, Chang XU, Kunming ZHANG, Jianglong WANG, Xiaojian HOU. Study on Fruit Quality of ‘Muscat Hamburg’ Grape Applied by Silicon Fertilizer in Root Zone [J]. Journal of Agricultural Science and Technology, 2023, 25(5): 215-223.
[13]	Xinci WANG, Junqiao LI, Chenqin LI, Tian TIAN, Junru QU. Identification and Biological Characteristics of a Thelonectria Pathogenic Fungi of Potentilla anserina L. [J]. Journal of Agricultural Science and Technology, 2023, 25(5): 87-95.
[14]	Xin JIN, Lu ZHANG, Peng WU, Ping LI, Wei TAN, Mingying GUI. Effects of Shading Treatment on Growth and Enzyme Activity of Bonsai Ganoderma lucidum [J]. Journal of Agricultural Science and Technology, 2023, 25(4): 147-156.
[15]	Hailong WEI, Yi CHENG, Bi SONG, Jun ZOU, Jin ZUO, Lei LI, Jun ZHANG, Dailing LIU, Tao ZENG, Jingfeng FU, Sheng WEI. Grain Filling Characteristics of Fresh Waxy Maize at Different Sowing Dates and Its Relationship with Meteorological Factors [J]. Journal of Agricultural Science and Technology, 2023, 25(4): 45-55.