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1.
《土壤通报》2018,(5)
N_2O是重要的温室气体之一,其增温效应是CO_2的150~200倍。旱地土壤是N_2O主要排放源,其排放通量在介于0~1000μg m~(-2) h-1,旱地作物生长期土壤N_2O排放通量一般呈现1~3次峰值。通过对旱地N_2O排放影响因素分析,总结出:正常施肥结合秸秆还田农民传统施肥或习惯性施肥优化施肥、优化施肥+有机肥、控释肥+有机肥、控释肥,有机肥有机无机混肥缓释尿素、生物质碳、硝化抑制剂;土壤N_2O的排放量与土壤含水量、土壤温度呈正相关,微咸水再生水、清水;栽培模式对旱地N_2O排放的影响不明确,结果存在分歧;单种作物混合作物;菜地玉米地小麦大豆;农林系统撂荒地农草系统纯玉米地系统;硝化和反硝化作用、土壤中的硝化细菌、地表温度、土壤温度、酸雨、土壤PH值等其他因素也影响N_2O的排放。 相似文献
2.
土地利用方式变化是造成大气中温室气体浓度变化的主要原因之一,但土地利用方式转变,如林地转变为耕地过程对土壤氧化亚氮(N_2O)排放的影响还缺乏系统研究。本研究于2016年7月中旬在四川盆地丘陵区将林地转变为耕地,并按照耕地冬小麦-夏玉米轮作方式,采用静态暗箱-气相色谱法,对比分析了耕地翻耕不施肥(CL-T)、翻耕施肥(CL-TF)和邻近林地(CK)的土壤N_2O排放过程特征。结果表明,试验期间CL-T、CL-TF土壤N_2O排放通量较CK均显著增加(P0.01),且二者的N_2O排放通量在林地转变为耕地初期均有明显的排放峰。小麦季和玉米季土壤N_2O排放通量[μg(N)·m-2·h-1]均值CK分别为2.52和4.60,CL-T分别为3.55和11.63,CL-TF分别为6.26和22.16,N_2O排放通量玉米季显著高于小麦季。CK、CL-T和CL-TF的土壤N_2O全年累积排放量[mg(N)·hm-2]分别为0.271、0.515和0.957,CL-T、CL-TF较CK分别显著增长89.8%、253.0%,说明林地转变为耕地,紫色土N_2O排放迅速增加。首先翻耕改变土壤结构并显著增加土壤无机氮含量(P0.05),其次施肥大幅增加土壤无机氮含量导致土壤N_2O的激发排放。而土壤温度和水分未发生显著改变(P0.05),种植作物短时间内也未显著改变土壤的N_2O排放。结果表明,林地转变为耕地激发土壤N_2O排放的根本机制可能是提高了土壤有机氮矿化速率。但土地利用转变对土壤氮转化过程的影响以及进而改变土壤N_2O的排放特征的机理有待进一步研究。 相似文献
3.
依托紫色土施肥方式与养分循环长期试验平台(2002年—),采用静态箱-气相色谱法开展紫色土冬小麦-夏玉米轮作周期(2013年10月至2014年10月)农田生态系统N_2O和NO排放的野外原位观测试验。长期施肥方式包括单施氮肥(N)、传统猪厩肥(OM)、常规氮磷钾肥(NPK)、猪厩肥配施氮磷钾肥(OMNPK)和秸秆还田配施氮磷钾肥(RSDNPK)等5种,氮肥用量相同[小麦季130 kg(N)×hm~(-2),玉米季150 kg(N)×hm~(-2)],不施肥对照(CK)用于计算排放系数,对比不同施肥方式对紫色土典型农田生态系统土壤N_2O和NO排放的影响,以期探寻紫色土农田生态系统N_2O和NO协同减排的施肥方式。结果表明,所有施肥方式下紫色土N_2O和NO排放速率波动幅度大,且均在施肥初期出现峰值;强降雨激发N_2O排放,但对NO排放无明显影响。在整个小麦-玉米轮作周期,N、OM、NPK、OMNPK和RSDNPK处理的N_2O年累积排放量分别为1.40 kg(N)×hm~(-2)、4.60 kg(N)×hm~(-2)、0.95 kg(N)×hm~(-2)、2.16kg(N)×hm~(-2)和1.41 kg(N)×hm~(-2),排放系数分别为0.41%、1.56%、0.25%、0.69%、0.42%;NO累积排放量分别为0.57 kg(N)×hm~(-2)、0.40 kg(N)×hm~(-2)、0.39 kg(N)×hm~(-2)、0.46 kg(N)×hm~(-2)和0.17 kg(N)×hm~(-2),排放系数分别为0.21%、0.15%、0.15%、0.17%、0.07%。施肥方式对紫色土N_2O和NO累积排放量具有显著影响(P0.05),与NPK处理比较,OM和OMNPK处理的N_2O排放分别增加384%和127%,同时NO排放分别增加3%和18%;RSDNPK处理的NO排放减少56%。表明长期施用猪厩肥显著增加N_2O和NO排放,而秸秆还田有效减少NO排放。研究表明,土壤温度和水分条件均显著影响小麦季N_2O和NO排放(P0.01),对玉米季N_2O和NO排放没有显著影响(P0.05),土壤无机氮含量则是在小麦-玉米轮作期N_2O和NO排放的主要限制因子(P0.01)。全量秸秆还田与化肥配合施用是紫色土农田生态系统N_2O和NO协同减排的优化施肥方式。 相似文献
4.
不同灌溉方式设施土壤N2O排放特征及其影响因素 总被引:4,自引:0,他引:4
为探明3种灌溉方式设施土壤N_2O排放特征及相关因素的影响,通过田间试验与室内分析相结合的方法,采用静态箱—气相色谱法与实时荧光定量PCR(Real-time PCR)技术分析不同灌溉方式(滴灌(D30)、渗灌(S30)、沟灌(G30))土壤N_2O排放特征的差异以及土壤温度、湿度、无机氮、反硝化细菌对土壤N_2O排放的影响。研究结果表明,灌溉后1~8d设施土壤会出现明显的N_2O排放高峰;整个番茄生长季沟灌处理土壤N_2O平均排放通量最大,分别较滴灌和渗灌处理高出52.74%和50.82%;与沟灌处理相比,滴灌处理和渗灌处理土壤N_2O排放总量分别降低了54.31%和53.30%。土壤N_2O排放与硝态氮含量(P0.05),土壤湿度呈极显著正相关(P0.01),与土壤温度、铵态氮含量之间关系不显著。不同灌溉方式土壤反硝化细菌丰度差异显著,表现为G30S30D30;土壤N_2O排放与反硝化细菌nosZ丰度呈极显著正相关(P0.01)。综上,土壤湿度、硝态氮、反硝化细菌nosZ是影响土壤N_2O排放的重要因素。与沟灌相比,滴灌与渗灌能够减少设施土壤N_2O排放量。 相似文献
5.
森林土壤氧化亚氮排放对大气氮沉降增加的响应研究进展 总被引:1,自引:1,他引:1
森林土壤N2O来源于土壤氮素的氧化还原反应,硝化、反硝化、硝化细菌反硝化以及化学反硝化是其产生的四个关键过程。当前,氮素富集条件下森林土壤N2O排放存在硝化和反硝化主导作用之争,对大气氮沉降增加的响应模式以及微生物驱动机制尚不清楚。综述了森林土壤N2O来源的稳定性同位素拆分,森林土壤总氮转化和N2O排放对增氮的响应规律,增氮对N2O产生菌群落活性和组成的影响,并指出研究的薄弱环节与未来的研究重点。总体而言,森林土壤N2O排放对大气氮沉降增加的响应呈现非线性,包括初期无明显响应、中期缓慢增加和后期急剧增加三个阶段,取决于森林生态系统"氮饱和"程度。施氮会引起森林土壤有效氮由贫氮向富氮的转变,相应地改变了土壤硝化细菌和反硝化细菌群落丰度与组成,进而影响土壤N2O排放。由于森林土壤N2O排放监测、土壤总氮转化和N2O产生菌群落动态研究多为独立进行的,难以阐明微生物功能群与N2O排放之间的耦合关系。未来研究应该有机结合15N-18O标记和分子生物学技术,准确量化森林土壤N2O的来源,揭示森林土壤N2O排放对增氮的非线性响应机理。 相似文献
6.
人为干扰对桂西北喀斯特生态系统土壤有机碳、氮、磷和微生物量剖面分布的影响 总被引:5,自引:0,他引:5
在桂西北喀斯特地区以原生林地为对照,选取了玉米-红薯轮作地、放牧+火烧草地和自然恢复地3种不同人为干扰的生态系统,研究土壤剖面养分、微生物活性对干扰强度的响应。结果表明,土壤有机碳和全氮随土壤深度的增加而降低,全磷变化较小,说明磷素主要来源于土壤母质,且淋溶作用较小;原生林地0-30 cm土壤有机碳、全氮、全磷、微生物量碳、氮、磷、碱解氮显著高于自然恢复地、放牧+火烧草地和玉米-红薯轮作地(p0.05),说明原生生态系统可维持较高的土壤肥力和微生物活性;3种人为干扰的生态系统,自然恢复地和放牧+火烧草地0-5 cm土壤有机碳含量显著高于玉米-红薯轮作地,说明自然恢复有利于提高表层土壤肥力和有机碳积累;玉米-红薯轮作地表层0-15 cm土壤全磷和有效磷含量显著高于自然恢复地和放牧+火烧草地,主要受施肥影响;60-100 cm,原生林地、自然恢复地和放牧+火烧草地土壤全氮显著高于玉米-红薯轮作地,说明农耕旱地土壤下层氮受雨水影响较大,淋失严重。自然恢复地和放牧+火烧草地表层(0-15 cm)土壤碱解氮、微生物量碳、氮、磷显著高于玉米-红薯轮作地,说明减少人为干扰和实行自然恢复可显著提高土壤氮的有效性和微生物活性。因此,提高农田管理水平、施行保护性耕作,推行自然恢复、减少人为干扰是提高喀斯特退化生态系统土壤生产力和增加土壤有机碳积累的有效措施。 相似文献
7.
采用室内培养法,比较分析了福建三明地区米槠次生林皆伐后火烧、保留采伐剩余物处理对土壤有机碳累积矿化量的影响,分析了土壤有机碳累积矿化量和土壤初始有机碳、微生物生物量碳及可溶性有机碳的关系。结果表明,火烧、保留采伐剩余物处理6个月和18个月后,火烧处理表层0~10 cm土壤有机碳含量较对照处理分别下降了6.0%和1.9%,保留采伐物处理土壤表层有机碳增加了15.6%和25.0%。两次培养中,火烧处理各土层累积矿化量显著低于对照和保留采伐剩余物处理;火烧6个月后,保留采伐剩余物处理各土层累积矿化量显著低于对照,18个月后10~20和20~40 cm土层累积矿化量显著高于对照处理。火烧18个月后,保留采伐剩余物处理各土层累积矿化量显著高于1年前的累积矿化量,分别高57.0%、112.0%和49.9%;火烧和对照处理前后两次培养各土层累积矿化量变化并无明显规律。土壤有机碳累积矿化量与土壤初始有机碳、微生物生物量碳和可溶性有机碳呈显著地线性相关关系(p0.05)。营林活动初期,皆伐后保留采伐剩余物措施较火烧能够增加土壤有机碳库,对土壤肥力及后期林木生长有重要的促进作用。 相似文献
8.
有机无机氮肥配施下洛阳烟田土壤N2O排放特点及其控制因素 总被引:1,自引:0,他引:1
随着农田化肥使用量的逐年增加和土壤退化问题日趋严重,农田温室气体排放关注度持续提高,为研究旱作植烟土壤N_2O排放特征及影响机理,设置6个田间试验处理,分别为CK0(不施肥处理)、CK1(100%无机氮)、T1(50%无机氮+50%饼肥氮)、T2(50%无机氮+50%羊粪肥氮)、T3(25%无机氮+75%饼肥氮)、T4(25%无机氮+75%羊粪肥氮),各处理施氮量均为45 kg/hm2,烟田施用基肥后起142天内测量不同处理土壤N_2O排放通量、硝态氮、铵态氮含量、根层温度和含水率。结果表明:(1)基肥施入后的3~7天内,土壤N_2O排放通量进入高峰,无机肥处理和有机无机肥配施处理的高峰期分别可维持20,9天,追肥后3天再次出现排放峰并持续9天,随后伴随烟株的生长发育,烟地N_2O排放通量逐渐趋向稳定。(2)基肥施用后仅1个月内N_2O累积排放量可达到总排放量的27.4%~32.6%;处理间N_2O排放量和排放系数均表现为无机>有机+无机(1∶1)>有机+无机(3∶1),无机肥配施有机肥明显降低了肥料中氮素以N_2O形态的损失量;与无机肥相比,T1和T2烟叶产量分别增加9.44%和6.37%,T1、T2、T3和T4处理的N_2O排放强度有着不同程度的降低。(3)主成分分析结果显示,在不施肥烟地中0—5 cm土壤温度和含水率是N_2O排放通量主导因子,利用相关性分析此环境下温度和水分分别与N_2O排放通量间呈现显著和极显著正相关关系;施肥后土壤铵态氮含量和土壤含水率是烟地N_2O排放通量的主导因子且相关性分析均呈现极显著正相关关系。综上,旱地植烟土壤N_2O排放受氮肥种类影响较大,施肥后N_2O排放通量对土壤温度响应减弱,主要受土壤铵态氮含量和含水量的影响;在总氮量相同情况下,有机无机肥配施比例为1∶1时明显降低土壤N_2O排放并提高了产量,该比例饼肥和羊粪肥处理分别将烟地N_2O排放强度降低20.4%和23.7%。 相似文献
9.
利用在线自动监测培养系统(Robot系统),研究不同氧分压、碳源投入以及不同氧分压和碳源投入组合下,添加硝化抑制剂双氰胺(DCD)对设施菜田土壤N_2O排放的影响。结果表明:随着土壤氧分压的升高,N_2O排放量呈指数下降(P0.001),土壤氧分压大于等于3%O_2后,N_2O排放量不足于无氧和微量氧(1%氧)处理的30%。添加碳源降低了有氧条件下土壤N_2O和N_2产生量,显著增加了微量氧下异养反硝化途径对N_2O的贡献量(P0.01)。在微量氧和3%O_2下,与未添加DCD的处理相比,无碳源添加且施用DCD后,N_2O的排放分别降低了64.4%和88.8%,同时N_2排放分别降低了23.4%和18.6%。从微量氧至3%O_2,虽然无碳源添加的处理硝化细菌反硝化作用对N_2O排放的贡献从17.2%增加至42.6%,但由于排放总量的急剧下降,硝化细菌反硝化作用对设施菜田土壤N_2O排放的贡献较小。本研究所用土壤pH较高,且添加DCD的处理培养前后硝酸盐基本平衡,异养的同步硝化-反硝化过程可能很弱。总之,设施菜田土壤N_2O排放主要发生在无氧和微量氧条件下。异养反硝化菌对土壤N_2O排放的直接贡献最大,尤其是在碳源较为充足的条件下。 相似文献
10.
施氮及添加硝化抑制剂对苜蓿草地N2O排放的影响 总被引:1,自引:0,他引:1
为探究旱作紫花苜蓿(MedicagosativaL.)栽培草地氧化亚氮(N_2O)排放对施氮水平及添加硝化抑制剂的响应特征,采用传统静态箱法研究了不同施氮水平[0kg(N)·hm~(-2)(N0)、 50kg(N)·hm~(-2)(N50)、 100kg(N)·hm~(-2)(N100)和150kg(N)·hm~(-2)(N150)]以及添加硝化抑制剂双氰胺(DCD)150kg(N)·hm~(-2)(N150+DCD)对陇东苜蓿草地N_2O排放特征的影响。结果显示,监测期内N0、N50、N100和N150处理N_2O平均排放速率分别为3.5μg·m~(-2)·h~(-1)、4.1μg·m~(-2)·h~(-1)、5.0μg·m~(-2)·h~(-1)和6.1μg·m~(-2)·h~(-1),随着施氮梯度的增加, N_2O排放速率呈增加趋势。添加硝化抑制剂DCD对N_2O排放产生明显的抑制作用。与N150处理相比, N150+DCD处理下苜蓿草地N_2O平均排放速率下降50.7%, N_2O累计排放量显著降低61.6%(P0.05)。施氮对苜蓿产量没有显著影响,而N0、N50、N100和N150处理下单位苜蓿产量N_2O排放量随氮肥梯度的增加而增加,各处理分别为6.5 mg·kg~(-1)、7.8 mg·kg~(-1)、11.3 mg·kg~(-1)和12.5 mg·kg~(-1)。N_2O排放受土壤含水量影响深刻,生长季N_2O排放通量与土壤水分呈显著正相关关系(P0.05),而与土壤温度无显著相关性(P0.05)。综上,旱作紫花苜蓿栽培草地N_2O排放通量随施氮水平的增加明显增加,在相同施氮水平下添加硝化抑制剂DCD能显著抑制N_2O排放。相关研究结果对于该区域苜蓿草地合理施肥以及N_2O减排具有一定的实践指导意义。 相似文献
11.
ABSTRACTThe objective of this work was to evaluate the variation in labile organic carbon fractions after the application of organic wastes (OWs) in semiarid soil under plastic mulched drip irrigation. The two-year experiment involved six treatments: chicken manure (CM), sheep manure (SM), mushroom residue (MR), maize straw (MS), fodder grass (FG), and tree leaves (TL), with an unamended soil (no OWs) as control. In 2015 and 2016, treatment with OWs led to increased levels of soil organic carbon (SOC), dissolved organic carbon, microbial biomass carbon, easily oxidized organic carbon, as well as higher carbon management indexes and yields and lower oxidation stability coefficients. Higher SOC contents (p <0.01) were achieved in both years for TL and MS compared to the other OWs. In particular, the SOC content in 2016 was higher (p <0.05) for TL than MS. Compared to the other OWs, the easily oxidized organic carbon levels and carbon management indexes in both years were higher (p <0.01) for CM, SM, and MS, whereas the oxidation stability coefficients were lower (p <0.01). In conclusion, among the studied treatments, the application of MS was the most effective for improving soil fertility and enhancing soil carbon sequestration. 相似文献
12.
生物炭施用下中国农田土壤N2O排放的Meta分析 总被引:1,自引:0,他引:1
为明确施加生物炭对中国农田土壤N_2O排放的影响和主要控制因素,以公开发表的试验数据为研究对象,采用Meta-analysis法定量分析了施加生物炭条件下,气候、土壤性质、田间管理方式、生物炭性质与施加量对土壤N_2O排放的影响,并对各影响因素进行通径分析。结果表明,当年降雨量≥600 mm时,生物炭显著降低土壤N_2O排放量(P0.05),且随年降雨量的增加而增强;当年日照时数大于1 000 h时,生物炭对土壤N_2O的减排效果随年日照时数的增加而减弱。当土壤p H≥6.5时,生物炭对土壤N_2O的减排效果随土壤p H的增加呈先增后减趋势;在壤土中施加生物炭对N_2O的减排效果显著(P0.05),而砂土和黏土不显著(P0.05)。生物炭对覆膜土壤N_2O的减排效果优于不覆膜土壤;生物炭对土壤N_2O的减排效果随施氮肥量增加而减弱,而随生物炭比表面积的增加而增强。当生物炭C/N处于30~500时,生物炭施用下土壤N_2O排放量显著降低(P0.05);当生物炭施加量处于20~160 t×hm-2时,生物炭对土壤N_2O的减排效果随施加量增加而增强。生物炭对土壤N_2O减排的影响存在显著的区域性特征,对华南、华东、华中和东北地区影响显著(P0.05),而对西北地区不显著(P0.05);施氮肥量、生物炭施加量、年均温和年降雨量是影响生物炭减排效果的最主要因素,这些因素的相互作用共同影响生物炭对土壤N_2O的减排效果。该研究可为生物炭在我国农区的推广应用和农田N_2O减排提供参考。 相似文献
13.
A 3-year field experiment was conducted in Jiangsu Province, China from 2004 to 2006 to investigate CH4 and N2O emissions from paddy fields as affected by various wheat straw management practices prior to rice cultivation. Five methods of returning wheat straw, no straw, evenly incorporating, burying straw, ditch mulching and strip mulching, were adopted in the experiment. Evenly incorporating is the most common management practice in the region. Results showed that compared with no straw, evenly incorporating increased CH4 emission significantly by a factor of 3.9-10.5, while decreasing N2O emission by 1-78%. Methane emission from burying straw was comparable with that from evenly incorporating, while N2O emission from burying straw was 94-314% of that from evenly incorporating. Compared with evenly incorporating, CH4 emission was decreased by 23-32% in ditch mulching and by 32% in strip mulching, while N2O emission was increased by a factor of 1.4-3.7 in ditch mulching and by a factor of 5.1 in strip mulching. During the rice-growing season, the emitted N2O was negligible compared to that of emitted CH4. No significant difference in grain yield was observed between ditch mulching, burying straw, evenly incorporating and no straw. Compared with no straw, the grain yield was increased by 27% in strip mulching. Based on these results, the best management practice for returning wheat straw to the soil is strip mulching wheat straw partially or completely onto the field surface, as the method reduced CH4 emission from rice fields with no decrease in rice yield. 相似文献
14.
水肥管理对稻田CH4排放及其全球增温潜势影响的评估 总被引:6,自引:1,他引:6
甲烷(CH_4)是主要温室气体之一,对全球增温的作用仅次于二氧化碳(CO_2)。稻田是CH_4的重要排放源,减少稻田CH_4排放对减缓气候变暖具有直接效应。为此,掌握稻田CH_4排放的规律和特征对控制和减少稻田CH_4排放尤为重要。为了解稻田温室气体排放的主要影响因子及影响程度,估算稻田温室气体全球增温潜势,寻求农田减排措施,我们通过收集已发表的文献建立了稻田CH_4排放的数据库,采用析因分析与回归分析方法对稻田CH_4日排放量和全球增温潜势特征和可能的影响因子进行了分析。结果表明,稻田CH_4日排放量和增温潜势均随土壤有机质背景含量的升高而增加,不同类型稻田CH_4日排放量大小依次为:双季稻晚稻双季稻早稻单季稻稻麦轮作晚稻;晚稻田CH_4的增温潜势大于早稻田。不同肥料处理条件下,稻田CH_4日排放量表现为:秸秆还田配施有机肥化学氮肥≈生物炭。控制灌溉水量可降低稻田CH_4的综合增温潜势,表现为:持续淹水晒田干湿交替控制灌溉。研究结果说明,稻田CH_4的产生与排放过程受土壤有机质含量、肥料管理和水分管理以及轮作制度等多种因素的共同影响,应依据不同土壤条件和种植制度,适当调整肥水管理,以减少稻田温室气体排放,降低其增温潜势。 相似文献
15.
L. Norberg Ö. Berglund K. Berglund 《Acta Agriculturae Scandinavica, Section B - Plant Soil Science》2016,66(7):602-612
Drainage of peatlands affects the fluxes of greenhouse gases (GHGs). Organic soils used for agriculture contribute a large proportion of anthropogenic GHG emissions, and on-farm mitigation options are important. This field study investigated whether choice of a cropping system can be used to mitigate emissions of N2O and influence CH4 fluxes from cultivated organic and carbon-rich soils during the growing season. Ten different sites in southern Sweden representing peat soils, peaty marl and gyttja clay, with a range of different soil properties, were used for on-site measurements of N2O and CH4 fluxes. The fluxes during the growing season from soils under two different crops grown in the same field and same environmental conditions were monitored. Crop intensities varied from grasslands to intensive potato cultivation. The results showed no difference in median seasonal N2O emissions between the two crops compared. Median seasonal emissions ranged from 0 to 919?µg?N2O?m?2?h?1, with peaks on individual sampling occasions of up to 3317?µg?N2O?m?2?h?1. Nitrous oxide emissions differed widely between sites, indicating that soil properties are a regulating factor. However, pH was the only soil factor that correlated with N2O emissions (negative exponential correlation). The type of crop grown on the soil did not influence CH4 fluxes. Median seasonal CH4 flux from the different sites ranged from uptake of 36?µg CH4?m?2?h?1 to release of 4.5?µg?CH4?m?2?h?1. From our results, it was concluded that farmers cannot mitigate N2O emissions during the growing season or influence CH4 fluxes by changing the cropping system in the field. 相似文献
16.
In order to study effects of sodium bicarbonate (NaHCO3) stress in irrigation water on photosynthetic characteristics and iron (Fe) and sodium (Na+) translocation content of pomegranate plants, a factorial experiment was conducted based on completely randomized design with three cultivars of pomegranate (“Gorch-e-Dadashi,” “Zagh-e-Yazdi,” and “Ghermez-e-Aliaghai”) and four concentrations of NaHCO3 (0, 5, 10, and 15 mM), with three replications. The results of plant analysis indicated that NaHCO3 affected chlorophyll index, Fv/Fm, and performance index (PI) in upper and lower leaves of shoots and also the translocation of Na+ and Fe. The results also showed that Fe translocation from root to shoot reduced at 15 mM level of NaHCO3. The highest Na translocation and the lowest Fe translocation were observed in Zagh-e-Yazdi and Ghermez-e-Aliaghai cultivars, respectively. The ratio of sodium/potassium (Na+/K+) in stems was higher than that in roots and leaves, and the observed chlorophyll content of upper leaves was also lower than that of lower leaves. Based on the measured parameters Gorch-e-Dadashi cultivar showed less relative sensitivity than other cultivars to NaHCO3 of irrigation water through maintaining the lower Na+ transport to the shoots, and improvement of Fe transport to shoots. 相似文献
17.
Michael Dannenmann Klaus Butterbach-Bahl Rainer Gasche Georg Willibald Hans Papen 《Soil biology & biochemistry》2008,40(9):2317
Reduction of nitrous oxide (N2O) to dinitrogen (N2) by denitrification in soils is of outstanding ecological significance since it is the prevailing natural process converting reactive nitrogen back into inert molecular dinitrogen. Furthermore, the extent to which N2O is reduced to N2 via denitrification is a major regulating factor affecting the magnitude of N2O emission from soils. However, due to methodological problems in the past, extremely little information is available on N2 emission and the N2:N2O emission ratio for soils of terrestrial ecosystems. In this study, we simultaneously determined N2 and N2O emissions from intact soil cores taken from a mountainous beech forest ecosystem. The soil cores were taken from plots with distinct differences in microclimate (warm-dry versus cool-moist) and silvicultural treatment (untreated control versus heavy thinning). Due to different microclimates, the plots showed pronounced differences in pH values (range: 6.3–7.3). N2O emission from the soil cores was generally very low (2.0 ± 0.5–6.3 ± 3.8 μg N m−2 h−1 at the warm-dry site and 7.1 ± 3.1–57.4 ± 28.5 μg N m−2 h−1 at the cool-moist site), thus confirming results from field measurements. However, N2 emission exceeded N2O emission by a factor of 21 ± 6–220 ± 122 at the investigated plots. This illustrates that the dominant end product of denitrification at our plots and under the given environmental conditions is N2 rather than N2O. N2 emission showed a huge variability (range: 161 ± 64–1070 ± 499 μg N m−2 h−1), so that potential effects of microclimate or silvicultural treatment on N2 emission could not be identified with certainty. However, there was a significant effect of microclimate on the magnitude of N2O emission as well as on the mean N2:N2O emission ratio. N2:N2O emission ratios were higher and N2O emissions were lower for soil cores taken from the plots with warm-dry microclimate as compared to soil cores taken from the cool-moist microclimate plots. We hypothesize that the increase in the N2:N2O emission ratio at the warm-dry site was due to higher N2O reductase activity provoked by the higher soil pH value of this site. Overall, the results of this study show that the N2:N2O emission ratio is crucial for understanding the regulation of N2O fluxes of the investigated soil and that reliable estimates of N2 emissions are an indispensable prerequisite for accurately calculating total N gas budgets for the investigated ecosystem and very likely for many other terrestrial upland ecosystems as well. 相似文献
18.
不同耕作措施下土壤N2O排放及其农学效率 总被引:2,自引:0,他引:2
为评价不同耕作措施下华北平原农田土壤N2O排放及其农学效率,通过设置常规耕作秸秆还田(CT+)、常规耕作无秸秆还田(CT?)、免耕秸秆还田(NT+)、免耕无秸秆还田(NT?)4个处理田间定位试验,采用静态箱?气相色谱法测定分析了连续3个小麦生长期的表层土壤N2O排放及其主要相关因子,同时测定了小麦产量与氮吸收量等相关指标。结果表明:在4个处理下,小麦生长期内表层土壤N2O排放动态基本一致,而土壤N2O累积排放量却存在显著差异,而且耕作方式与秸秆还田存在显著的互作效应。在常规耕作和免耕措施下,单位面积土壤N2O累积排放量均表现为秸秆还田土壤显著高于无秸秆还田土壤,CT+和NT+分别比CT?和NT?高26.2%和74.6%;在无秸秆还田条件下,土壤N2O排放量表现为常规耕作比免耕高42.4%。相关分析表明,土壤N2O排放通量与地下5 cm土壤温度、土壤孔隙充水率(WFPS)之间呈显著正相关关系,与土壤溶解性有机氮(DON)含量之间呈显著负相关关系。利用农学效率指标度量N2O排放量时可知,虽然小麦籽粒产量和氮肥偏生产力在各处理间没有达到显著性差异,但每生产1 kg小麦籽粒表层土壤N2O排放量为0.18~0.73 g N2O-N,每投入1 kg氮素表层土壤N2O排放量为5.1~18.0 g N2O-N,处理间存在显著差异;与单位面积土壤N2O排放量表现一致,单位籽粒产量N2O排放量和单位氮素投入N2O排放量均表现为无论是常规耕作还是免耕措施,秸秆还田土壤均显著高于秸秆不还田土壤,在秸秆不还田条件下,常规耕作土壤均显著高于免耕土壤。总之,免耕是有效减少土壤N2O排放的一种耕作措施。 相似文献
19.
D. Akbolat A. Coskan K. Ekinci 《Acta Agriculturae Scandinavica, Section B - Plant Soil Science》2013,63(1):50-56
Abstract The study aimed at quantifying the rates of soil CO2 efflux under the influence of common tillage systems of moldboard plow (PT), chisel plow (CT), rotary tiller (RT), heavy disc harrow (DT), and no-tillage (NT) for 46 days in October and November in a field left fallow after wheat harvest located in southern Turkey. The NT and DT plots produced the lowest soil CO2 effluxes of 0.3 and 0.7 g m?2 h?1, respectively, relative to the other plots (P < 0.001). Following the highest rainfall amount of 87 mm on the tenth day after the tillage, soil CO2 efflux rates of all the plots peaked on the 12th day, with less influence on soil CO2 efflux in the NT plot than in the conventional tillage plots. Soil evaporation in NT (64 mmol m?2 s?1) was significantly lower than in the PT (85 mmol m?2 s?1) and RT (89 mmol m?2 s?1) tillage treatments (P < 0.01). The best multiple-regression model selected explained 46% of variation in soil respiration rates as a function of the tillage treatments, soil temperature, and soil evaporation (P < 0.001). The tillage systems of RT, PT, and CT led, on average, to 0.23, 0.22, and 0.18 g m?2 h?1 more soil CO2 efflux than the baseline of NT, respectively (P≤0.001). 相似文献
20.
AbstractWe investigated the effect of foliar application of potassium nitrate (KNO3) and zinc sulfate (ZnSO4) on the fruit quality of pomegranate (Punica granatum L. cv. Malas-E–Torsh in Saveh). Potassium was applied as KNO3 at concentrations of 0%, 0.25%, and 0.5% and zinc was applied as ZnSO4 at concentrations of 0%, 0.5%, and 1% in a completely randomized block design. To determine the effect of the treatments on fruit quality, we measured fruit weight, peel thickness, aril diameter, phenol content of the juice, pH, total soluble solids (TSS), titratable acidity (TA), and antioxidant capacity. Foliar application of KNO3 significantly increased fruit weight, 100 aril weight, peel weight, peel thickness, TTS, and antioxidant capacity. In contrast, pH, TA, TSS/TA, and phenol content of the juice were not influenced by foliar application of KNO3. ZnSO4 significantly increased fruit weight, aril diameter, and phenol content of the juice. KNO3 1% and ZnSO4 0.5% were identified as the most appropriate treatments in improving quality and quantity of pomegranate. The fatty acid profile of the pomegranate oil was primarily composed of punicic acid, linoleic acid, oleic acid, palmitic acid, and stearic acid. 相似文献