Increasing the planting density can exacerbate crop competition for water, nutrients and space which results in a decline in the crop yields. However, the effect of increasing planting density on crop growth and soil biological characteristics in barren sandy land in the semi-arid regions are still unclear. In this study, we investigated the effects of six planting densities (5.4×104, 6.45×104, 7.95×104, 9.5×104, 9.75×104 and 10.5×104 plants/hm2) on maize growth, photosynthesis characteristics, yield and soil biological characteristics in barren sandy soil in the semi-arid region of Ningxia, China. The results indicated that the stem diameter and spike length decreased linearly with increasing planting density. The plant height, spike weight, grain weight and 100-grain weight decreased with increasing plating density. Moreover, the root length increased with increasing planting density. The diameter, volume and activity increased and then decreased with increasing planting density. There was no significant difference (p>0.05) in the effect of planting density on transpiration rate intercellular CO2 concentration. As well, the soil microbial biomass carbon and microbial biomass nitrogen decreased with increasing planting density. The soil catalase activities increased and then decreased with increasing planting density. The alkaline phosphatase activity, the amounts of soil bacteria and actinomycetes increased with increasing planting density. Generally, a moderately increasing planting density can improve maize yield when water and nutrients are sufficient. The optimal planting density was 8.29×104 plants/hm2 and the highest yield was 15.84 t/hm2 in barren sandy soil in semi-arid region of Ningxia, China. This study provides a theoretical basis for high yield and high efficiency of maize.
Key words: maize growth, planting density, yield, fertigation, soil enzyme activity
DOI: 10.25165/j.ijabe.20241702.8090

DOI: 10.25165/j.ijabe.20241702.8090
Citation: Jiang P, Li L, Xu D J, Wang R, Sun Q. Response of maize growth and soil biological characteristics to planting
density under fertigation in a semi-arid region. Int J Agric & Biol Eng, 2024; 17(2): 186–192.

maize growth, planting density, yield, fertigation, soil enzyme activity

Boomsma C R, Santini J B, Tollenaar M, Vyn T J. Maize morphophysiological responses to intense crowding and low nitrogen availability: An analysis and review. Agronomy Journal, 2009; 101(6): 1426–1452.

Assefa Y, Vara Prasad P V, Carter P, Hinds M, Bhalla G, Schon R, et al. Yield responses to planting density for US modern corn hybrids: A synthesis-analysis. Crop Science, 2016; 56(5): 2802–2817.

Lu H D, Xue J Q, Hao Y C, Zhang X H, Zhang R H, Gao J. Effects of planting densities on the yields and forage nutritive values of different corn (Zea mays L.) varieties. Acta Agrestia Sinica, 2014; 22(4): 865–870. (in Chinese)

Zhang J W, Hu C H, Wang K J, Dong S T, Liu P. Effects of plant density on forage nutritive values of whole plant corn. Scientia Agricultura Sinica, 2005; 38(6): 1126–1131. (in Chinese)

Zhang J X, Cai X Y, Wang S, Qin W H, Cui S H. Effects of density and cutting height on yield and forage nutritive quality of sequential cropping silage maize. Journal of maize science, 2006; 14(4): 107–110. (in Chinese)

Liu G Z, Hou P, Xie R Z, Ming ., Wang K R, Xu W J, et al. Canopy characteristics of high-yield maize with yield potential of 22.5 Mg ha−1. Field Crops Research, 2017; 213: 221–230.

Shang H Y. Effects of maize planting density on soil AM fungi characteristics and its mechanism. Master dissertation. Yangling: Northwest A&F University, 2022; 53p. (in Chinese)

Cha F N, Ma D Y, Guo T C, Song X, Yue Y J, Xie Y X. Dynamic changes of soil enzyme activity in rhizosphere of two spike-type winter wheat cultivars with different planting densities. Journal of Soil and Water Conservation, 2007; 21(2): 104–107. (in Chinese)

Ma D Y, Guo T C, Cha F N, Yue Y J, Song X. Effects of planting densities on microorganism population and soil enzyme activity in the rhizosphere of wheat. Acta Agriculturae Boreali-Sinica, 2008; 23(3): 154–157. (in Chinese)

Bao S D. Soil Agrochemical analysis. Beijing: China Agriculture Press. 2000. 495 p. (in Chinese)

Ma X X, Wang L L, Li Q H, Li H, Zhang S L, Sun B H, Yang X Y. Effects of long-term fertilization on soil microbial biomass carbon and nitrogen and enzyme activities during maize growing season. Acta Ecologica Sinica, 2012; 32(17): 5502–5511. (in Chinese)

Zhang G X, Guo X F, Zhu Y Z, Liu X T, Han Z W, Sun K, et al. The effects of different biochars on microbial quantity, microbial community shift, enzyme activity, and biodegradation of polycyclic aromatic hydrocarbons in soil. Geoderma, 2018; 328: 100–108.

Rice C W, Moorman T B, Beare M. Role of microbial biomass carbon and nitrogen in soil quality. Methods for Assessing Soil Quality, 1997; 49: 203–215.

Chen S Y, Li S F, Zhu J Y. Effects of planting density on rhizosphere soil characteristics and seed yield of wheat. Jiangsu Agricultural Sciences, 2016; 44(4): 132–137. (in Chinese)

Khush G. S. Green revolution: preparing for the 21st century. Genome, 1999; 42(4): 646–655.

Sharma L K, Bu H, Franzen D W, Denton A. Use of corn height measured with an acoustic sensor improves yield estimation with ground based active optical sensors. Computers and Electronics in Agriculture, 2016; 124: 254–262.

Liu W M, Liu G Z, Yang Y S, Guo X X, Ming B, Xie R Z, et al. Spatial variation of maize height morphological traits for the same cultivars at a large agroecological scale. European Journal of Agronomy, 2021; 130: 126349.

Zhang J W, Dong S T, Wang K J, Hu C H, Liu P. Effects of shading on the growth, development and grain yield of summer maize. Journal of Applied Ecology, 2006; 17(4): 657–662. (in Chinese)

Cui H Y, Jin L B, Li B, Zhang J W, Zhao B, Dong S T, et al. Effects of shading on stalks morphology, structure and lodging of summer maize in field. Scientia Agricultura Sinica, 2012; 45(17): 3497–3505. (in Chinese)

Zhang H S, Zhao M, Wu P B, Zhai Y J, Jiang W. Effects of the plant density on the characteristics of maize stem and ear. Journal of Maize Science, 2009; 17(5): 130–133. (in Chinese)

Lashkari M, Madani H, Ardakani M R, Golzardi F, Zargari K. Effect of plant density on yield and yield components of different corn (Zea mays L.) hybrids. American-Eurasian Journal of Agriculture and Environmental Sciences, 2011; 10(3): 450–457.

Lai Z L, Fan J L, Yang R, Xu X Y, Liu L J, Li S E, et al. Interactive effects of plant density and nitrogen rate on grain yield, economic benefit, water productivity and nitrogen use efficiency of drip-fertigated maize in northwest China. Agricultural Water Management, 2022; 263: 107453.

Niknam N, Faraji H. Effect of plant density and nitrogen on yield and yield components of maize var. 704. Applied Field Crops Research, 2014; 27(102): 54–60.

Abuzar M R, Sadozai G U, Baloch M S, Baloch A A, Shah I H, Javaid T, et al. Effect of plant population densities on yield of maize. The Journal of Animal & Plant Sciences, 2011; 21(4): 692–695.

Zhang Q, Zhang L Z, Evers J, van der Werf W, Zhang W Q, Duan L S. Maize yield and quality in response to plant density and application of a novel plant growth regulator. Field Crops Research, 2014; 164: 82–89.

Djaman K, Allen S, Djaman D S, Koudahe K, Irmak S, Puppala N, et al. Planting date and plant density effects on maize growth, yield and water use efficiency. Environmental Challenges, 2022; 6: 100417.

Dai J L, Tian L W, Zhang Y J, Zhang D M, Xu S Z, Cui Z P, et al. Plant topping effects on growth, yield, and earliness of field-grown cotton as mediated by plant density and ecological conditions. Field Crops Research, 2022; 275: 108337.

Niu L, Yan Y Y, Hou P, Bai W B, Zhao R L, Wang Y H, et al. Influence of plastic film mulching and planting density on yield, leaf anatomy, and root characteristics of maize on the Loess Plateau. The Crop Journal, 2020; 8(4): 548–564.

Jia Q M, Chen K Y, Chen Y Y, Ali S, Manzoor, Sohail A, et al. Mulch covered ridges affect grain yield of maize through regulating root growth and root-bleeding sap under simulated rainfall conditions. Soil and Tillage Research, 2018; 175: 101–111.

Li H B, Wang X, Brooker R W, Rengel Z, Zhang F S, Davies W J, et al. Root competition resulting from spatial variation in nutrient distribution elicits decreasing maize yield at high planting density. Plant and Soil, 2019; 439: 219–232.

Haj-Amor Z, Araya T, Kim D G, Bouri S, Lee J, Ghiloufi W, et al. Soil salinity and its associated effects on soil microorganisms, greenhouse gas emissions, crop yield, biodiversity and desertification: A review. Science of The Total Environment, 2022; 843: 156946.

Qiao Q H, Wang F R, Zhang J X, Chen Y, Zhang C Y, Liu G D, et al. The variation in the rhizosphere microbiome of cotton with soil type, genotype and developmental stage. Scientific reports, 2017; 7: 3940.

de Sousa R S, Nunes L A P L, Antunes J E L, de Araujo A S F. Maize rhizosphere soil stimulates greater soil microbial biomass and enzyme activity leading to subsequent enhancement of cowpea growth. Environmental Sustainability, 2019; 2: 89–94.

Li L, Xu M G, Eyakub Ali M, Zhang W J, Duan Y H, Li D C. Factors affecting soil microbial biomass and functional diversity with the application of organic amendments in three contrasting cropland soils during a field experiment. PLOS One, 2018; 13(9): e0203812.

Ren Q S, Song H, Yuan Z X, Ni X L, Li C X. Changes in soil enzyme activities and microbial biomass after revegetation in the Three Gorges Reservoir, China. Forests, 2018; 9(5): 249.

Wang G S, Gao Q, Yang Y F, Sarah E H, Peter B R, Zhou J Z. Soil enzymes as indicators of soil function: A step toward greater realism in microbial ecological modeling. Global Change Biology, 2022; 28(5): 1935–1950.