Effects of steel slag mixed substrate on rooting of Hydrangea macrophylla cuttings

doi:10.13287/j.1001-9332.202408.015

Abstract

Abstract: To investigate the effect of steel slag used as substrate on the rooting of Hydrangea macrophylla cuttings, and to develop a new mixed substrate that can partially replace conventional cutting substrates and realize the high-efficient utilization of solid waste, we examined the physical and chemical properties of different mixed substrates containing 10% (T₁), 20% (T₂), 30% (T₃), and 40% (T₄) volume fractions of steel slag, and investigated the rooting of H. macrophylla ‘Red Beauty’ cuttings growing on these substrates, with conventional cutting substrates (peat and perlite) as the control (CK). The results showed that pH value, electrical conductivity, and bulk density of the mixed substrates were significantly higher than those of CK. The aeration porosity of T₂ was higher than other treatments, while the total porosity and water holding porosity differed little from others. Both fresh weight and dry weight of all the four treatments were higher than those of CK, with stem diameter being higher than that of CK (except T₄), plant height showing no significant difference compared to CK (except T₄), and leaf chlorophyll content being significantly lower than CK. Root length ranked as T₂>CK>T₁>T₃>T₄, the root surface area and root volume both ranked as T₂>T₁>CK>T₄>T₃, the root tip ranked as T₂>CK>T₁>T₄>T₃. Both average root diameter and root activity were significantly higher than that of CK, with the highest value being observed in T₂. Soluble sugar content in the leaves of T₂ was the highest, followed by T₄, T₃, CK, and T₁. The weight ranking of root growth indices was root activity > average root diameter > root volume > root surface area > root tip number > root length. Redundancy analysis indicated that pH value, electrical conductivity, aeration porosity, and water holding porosity of substrates were key factors influencing root growth and development of cuttings. Our results suggested that substrates mixed with 10% to 40% steel slag could be used for H. macrophylla cutting propagation, and 20% (T₂) being the best one because it could significantly improve the survival rate, growth status, and root development of cuttings. Steel slag would be a novel substrate to partially replace conventional unrenewable substrates such as peat and perlite for flower seedling propagation, which could reduce agricultural production cost and provide a high-value utilization way of industry solid waste.

Key words: steel slag, Hydrangea macrophylla, rooting of cutting, mixed substrate, solid waste

MAO Jundan, CHEN Huijie, QI Xiangyu, CHEN Shuangshuang, FENG Jing, JIN Yuyan, DENG Yanming, ZHANG Hao. Effects of steel slag mixed substrate on rooting of Hydrangea macrophylla cuttings[J]. Chinese Journal of Applied Ecology, 2024, 35(8): 2150-2158.

References

[1] 张俊, 严定鎏, 齐渊洪, 等. 钢铁冶炼渣的处理利用难点分析. 钢铁, 2020, 55(1): 1-5
[2] 曹杨. 盛隆冶金钢渣在道路工程中应用的可行性研究. 西部交通科技, 2019(10): 44-47
[3] Na H, Wang YJ, Zhang X, et al. Hydration activity and carbonation characteristics of dicalcium silicate in steel slag: A review. Metals, 2021, 11: 1580
[4] 王安, 吴美玲, 李忠元, 等. 钢渣应用于土壤修复的研究进展. 环境工程技术学报, 2023, 13(4): 1535-1543
[5] 贺礼, 陈跃进, Elena B, 等. 钢渣硅肥对水稻产量及稻田重金属污染治理作用研究进展. 现代农业科技, 2018(9): 232-233
[6] Chen SS, Qi XY, Feng J, et al. Biochemistry and transcriptome analyses reveal key genes and pathways involved in high-aluminum stress response and tolerance in hydrangea sepals. Plant Physiology and Biochemistry, 2022, 185: 268-278
[7] Qi XY, Chen SS, Wang HD, et al. Comparative physio-logy and transcriptome analysis reveals that chloroplast development influences silver-white leaf color formation in Hydrangea macrophylla var. maculata. BMC Plant Biology, 2022, 22: 345
[8] 江胜德. 2022中国商品绣球消费状况年度报告. 武汉: 湖北科学技术出版社, 2022
[9] 黄灵, 郝春磊, 张黎. 不同品种八仙花硬枝和嫩枝扦插生根能力的比较. 农业科学研究, 2021, 42(4): 79-83
[10] Zhang PJ, Zhang GW, Shang XH. Effect of different peat substitute substrates on the growth and quality of seedlings of Handroanthus chrysanthus (Jacq.) SO Grose. Forests, 2022, 13: 1626
[11] 白莉萍, 宋金洪, 辛涛, 等. 施用城市污泥对小叶黄杨光合特性和生长的影响. 应用生态学报, 2010, 21(4): 1026-1030
[12] 马凡强, 简尊吉, 郭泉水, 等. 不同农林废弃物混合基质对崖柏扦插育苗的影响. 应用生态学报, 2023, 34(7): 1817-1824
[13] 刘鹏耀, 张喜, 李国鹏, 等. 冷态钢渣水化活性激发研究现状及展望. 华北理工大学学报: 自然科学版, 2024, 46(1): 52-58
[14] Tian Y, Sun XY, Li SY, et al. Biochar made from green waste as peat substitute in growth media for Calathea rotundifola cv. fasciata. Scientia Horticulturae, 2012, 143: 15-18
[15] 郭士荣. 无土栽培学. 北京: 中国农业出版社, 2005
[16] 丁岳炼, 王冰清, 陈杰, 等. 不同基质配比对短序润楠容器苗生长的影响. 湖北农业科学, 2023, 62(11): 92-96
[17] 任玉连, 董醇波, 邵秋雨, 等. 冗余分析在微生物生态学研究中的应用. 山地农业生物学报, 2022, 41(1): 41-48
[18] 陈金玲, 谢健, 孙燕, 等. 基质配比对培忠杉容器苗生长的影响[EB/OL]. (2023-05-06)[2024-04-02]. 分子植物育种, https://kns.cnki.net/kcms/detail/46.1068.S.20230505.1318.010.html
[19] 武春成, 李天来, 曹霞, 等. 营养基质对连作栽培下温室黄瓜生长及土壤微环境的影响. 应用生态学报, 2014, 25(5): 1401-1407
[20] Xu S, Chen AT, Wang YJ, et al. Effects of blast furnace slag on the immobilization, plant uptake and translocation of Cd in a contaminated paddy soil. Environment International, 2023, 179: 108162
[21] 涂佳丽, 杨娟, 周燕, 等. 土壤pH对八仙花花色调节的作用探究. 上海农业科技, 2022(1): 93-94
[22] 徐慧, 刘超, 钟汉东. 不同光照强度对八仙花开花的影响. 北方园艺, 2014(1): 81-82
[23] 王新右. 蔬菜栽培与基质理化性状的关系探讨. 现代农业科技, 2018(13): 76-77
[24] Feng XQ, Zhang L. Vermiculite and humic acid improve the quality of green waste compost as a growth medium for Centaurea cyanus L. Environmental Technology & Innovation, 2021, 24: 101945
[25] 何凌枫, 陈晨, 邓元杰, 等. 基质配比对胡萝卜根系生长及生理特性的影响. 中国农学通报, 2023, 39(16): 12-19
[26] South DB, Menzies MI, Holden DG. Stock size affects outplanting survival and early growth of fascicle cuttings of Pinus radiata. New Forests, 2005, 29: 273-288
[27] Hu WS, Lu ZF, Meng FJ, et al. The reduction in leaf area precedes that in photosynthesis under potassium deficiency: The importance of leaf anatomy. New Phyto-logist, 2020, 227: 1749-1763
[28] 魏溧姣, 王晓明, 王湘莹, 等. 不同基质对紫叶紫薇容器苗生长及生理特性的影响. 中南林业科技大学学报, 2023, 43(4): 10-19
[29] 卢万义, 覃创羿, 鲁宗翰, 等. 不同基质配比对沃柑大苗生长、生理及光合特性的影响. 中国果树, 2023(3): 79-84
[30] 吴俊宏, 张文豹, 荣晗琳, 等. 不同栽培基质对桔梗幼苗生长及生理指标的影响. 中国野生植物资源, 2023, 42(4): 56-61
[31] Robles-Aguilar AA, Pang JY, Postma JA, et al. The effect of pH on morphological and physiological root traits of Lupinus angustifolius treated with struvite as a recycled phosphorus source. Plant and Soil, 2019, 434: 65-78
[32] Yang Y, Liu BM, Ni XY, et al. Rice productivity and profitability with slow-release urea containing organic-inorganic matrix materials. Pedosphere, 2021, 31: 511-520
[33] Li N, Yang Y, Wang LQ, et al. Combined effects of nitrogen and sulfur fertilization on maize growth, physiological traits, N and S uptake, and their diagnosis. Field Crops Research, 2019, 242: 107593
[34] 吴雅薇, 李强, 豆攀, 等. 低氮胁迫对不同耐低氮玉米品种苗期伤流液性状及根系活力的影响. 植物营养与肥料学报, 2017, 23(2): 278-288
[35] Wu Y, Wang HZ, Yang XW, et al. Soil water effect on root activity, root weight density, and grain yield in winter wheat. Crop Science, 2017, 57: 437-443
[36] 胡雨彤, 时连辉, 刘登民, 等. 不同比例珍珠岩对污泥堆肥理化性状与孔雀草生长的影响. 应用生态学报, 2014, 25(7): 1949-1954
[37] 刘晚苟, 何泳怡, 谢海容, 等. 设施砂壤土容重对番茄幼苗生长和根系构型的影响. 园艺学报, 2015, 42(7): 1313-1320
[38] 王德玉, 孙艳, 郑俊鶱, 等. 土壤紧实胁迫对黄瓜根系生长及氮代谢的影响. 应用生态学报, 2013, 24(5): 1394-1400
[39] 彭丹丹, 陈大刚, 徐开未, 等. 椰糠复合基质对猕猴桃砧木幼苗生长及根系特征的影响. 浙江农业学报, 2023, 35(10): 2364-2377
[40] 崔晓明, 张亚如, 张晓军, 等. 土壤紧实度对花生根系生长和活性变化的影响. 华北农学报, 2016, 31(6): 131-136
[41] 邢书慧, 罗健, 陈泳慧, 等. 通气对几种水培观赏植物生长的影响. 农业工程学报, 2005, 21(增刊2): 36-40