|Table of Contents|

Effects of Aeration on the Growth of Figs and the Uptake and Transformation of Soil Phosphorus in Southern Xinjiang Facilities

《北方园艺》[ISSN:1001-0009/CN:23-1247/S]

Issue:
2024年19
Page:
38-45
Research Field:
Publishing date:

Info

Title:
Effects of Aeration on the Growth of Figs and the Uptake and Transformation of Soil Phosphorus in Southern Xinjiang Facilities
Author(s):
CUI JingWANG JunwuZHAO FengyunWANG JunBAI RuxiaoYU Kun
(College of Agronomy,Shihezi University/Key Laboratory of Characteristic Fruit and Vegetable Cultivation Physiology and Germplasm Resource Utilization Corps,Shihezi,Xinjiang 832003)
Keywords:
aerated irrigationfacilities figsphosphorus uptake and transformation efficiency
PACS:
S 628
DOI:
10.11937/bfyy.20241383
Abstract:
Taking ‘Braunschweig’ fig plants as the test materials,four treatments were set up,aerated phosphorus fertilizer (OP),aerated without phosphorus fertilizer (OF),phosphate fertilizer without aerated fertilizer (NP),and without phosphate fertilizer without aerated fertilizer (NF),effects of aeration on the growth of figs and the uptake and transformation of soil phosphorus in Southern Xinjiang facilities were studied,in order to provide reference for the application of drip gas storage and gas injection technology in the facility figs.The results showed that OP,OF and NP could promote the growth of fig plants,increase the soil water content and adjust the soil pH value of each soil layer to different extents.Among them,OP at 30-80 days and OF at 50-80 days significantly promoted the growth of new shoots of figs.In the 0-20 cm soil layer,the soil moisture content of OP,OF and NP decreased by 15.02%,9.84% and 1.98%,respectively,compared with NF.Compared with NF treatment,OP treatment could significantly increase the soil acid phosphatase activity in each soil layer,and the soil acid phosphatase activity of 0-20 cm soil layer was the best,which increased by 157.37%,and the soil available phosphorus content of OP Treatment increased by 212.82%,160.79% and 98.77% in the three soil layers of 0-20 cm,20-40 cm and 40-60 cm,respectively.In conclusion,the aerated treatment had a promoting effect on the growth of ‘Braunschweig’ fig plants and the conversion of soil total phosphorus to available phosphorus.

References:

[1]孙蕾,房用.无花果及其开发的前景[J].山东林业科技,1993,23(4):62-65.[2]刘薇,单承莺,聂韡,等.无花果多糖的研究与开发进展[J].中国野生植物资源,2022,41(10):60-64.[3]艾沙江·阿不都沙拉木,杨培,买买提江·吐尔逊,等.无花果在阿图什维吾尔族民间的传统应用的调查研究[J].植物分类与资源学报,2015,37(2):214-220.[4]倪明霞,段峥嵘,夏建新.新疆南疆周边高山冰川融化及其未来水资源安全风险[J].山地学报,2022,40(3):329-342.[5]邓铭江.中国西北“水三线” 空间格局与水资源配置方略[J].地理学报,2018,73(7):1189-1203.[6]孙宇.新疆水资源经济生态系统韧性协调分析及未来预测[J/OL].人民长江,(2024-01-29)[2024-06-27].http://kns.cnki.net/kcms/detail/42.1202.TV.20240129.1105.002.html.[7]LIANG Q,LIU Y,ZHANG H,et al.Sub-surface drip irrigation reduced N2O emissions via inhibiting denitrification pathways in Northern China[J].Applied Soil Ecology,2023,191:105057.[8]滕晓波.根际加氧灌溉对烟草根系及其农艺性状的影响规律的研究[D].长沙:湖南农业大学,2013.[9]BEN-NOAH I,FRIEDMAN S P.Oxygation of clayey soils by adding hydrogen peroxide to the irrigation solution:Lysimetric experiments[J].Rhizosphere,2016,2:51-61.[10]KLRING H P,ZUDE M.Sensing of tomato plant response to hypoxia in the root environment[J].Scientia Horticulturae,2009,122(1):17-25.[11]于珍珍,汪春,李嘉熙,等.增氧灌溉系统的优化设计[J].农机化研究,2019,41(10):106-110.[12]李明军.植物与植物生理[M].重庆:重庆大学出版社,2015.[13]曾招兵,曾思坚,汤建东,等.广东省耕地土壤有效磷时空变化特征及影响因素分析[J].生态环境学报,2014,23(3):444-451.[14]刘志平,武雪萍,李若楠,等.温室滴灌条件下施用鸡粪和磷肥对土壤磷素的影响[J].中国农业科学,2019,52(20):3637-3647.[15]樊红柱,陈庆瑞,郭松,等.长期不同施肥紫色水稻土磷的盈亏及有效性[J].植物营养与肥料学报,2018,24(1):154-162.[16]李延树,肖满,赵丰云,等.穴贮砖对沙地梨树养分含量及土壤理化性质的影响[J].北方园艺,2024(4):66-73.[17]BHATTARAI S P,SU N,MIDMORE D J.Oxygation unlocks yield potentials of crops in oxygen-limited soil environments[J].Advances in Agronomy,2005,88:313-377.[18]BEN-NOAH I,FRIEDMAN S P.Aeration of clayey soils by injecting air through subsurface drippers:Lysimetric and field experiments[J].Agricultural Water Management,2016,176:222-233.[19]BHATTARAI S P,MIDMORE D J,PENDERGAST L.Yield,water-use efficiencies and root distribution of soybean,chickpea and pumpkin under different subsurface drip irrigation depths and oxygation treatments in vertisols[J].Irrigation Science,2008,26(5):439-450.[20]朱艳,蔡焕杰,宋利兵,等.加气灌溉对番茄植株生长、产量和果实品质的影响[J].农业机械学报,2017,48(8):199-211.[21]NIU W Q,ZANG X,JIA Z X,et al.Effects of rhizosphere ventilation on soil enzyme activities of potted tomato under different soil water stress[J].CLEAN-Soil,Air,Water,2012,40(3):225-232.[22]胡德勇,姚帮松,SU N H,等.增氧灌溉对秋黄瓜根系生长的影响[J].西北农业学报,2016,25(8):1224-1228.[23]尹伊君,毛云飞,杨露,等.增氧灌溉对平邑甜茶生长及根区土壤的影响[J].林业科学,2021,57(10):59-70.[24]王振华,韩美琪,宋利兵,等.加气对西北旱区膜下滴灌棉花生长与水分利用效率的影响[J].农业工程学报,2022,38(14):108-116.[25]曹雪松,李和平,郑和祥,等.加气灌溉对根区土壤肥力质量与作物生长的影响[J].干旱地区农业研究,2020,38(1):183-189.[26]王森,唐蛟,王晓森,等.加气灌溉对土壤、作物生长和水肥利用的影响综述[J].江苏农业科学,2019,47(7):24-27.[27]李元,牛文全,许健,等.加气滴灌提高大棚甜瓜品质及灌溉水分利用效率[J].农业工程学报,2016,32(1):147-154.[28]赵丰云,杨湘,董明明,等.加气灌溉改善干旱区葡萄根际土壤化学特性及细菌群落结构[J].农业工程学报,2017,33(22):119-126.[29]周礼恺,严昶昇,武冠云,等.土壤肥力实质的研究Ⅲ.红壤[J].土壤学报,1986,23(3):193-203.[30]李燕强,王振华,叶含春,等.灌溉水矿化度对棉田土壤呼吸速率的影响[J].干旱区研究,2023,40(3):392-402.[31]李元,牛文全,张明智,等.加气灌溉对大棚甜瓜土壤酶活性与微生物数量的影响[J].农业机械学报,2015,46(8):121-129.[32]张健利,王振华,宗睿,等.水气互作对滴灌加工番茄生长及品质的影响[J].江苏农业学报,2022,38(2):453-461.[33]顾惠敏,陈波浪,王庆惠.施磷对不同质地棉田土壤磷素有效性及磷肥利用率的影响[J].中国土壤与肥料,2019(3):100-108.

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Last Update: 2024-10-21