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1.
毛竹是我国南方广泛分布的一种典型的森林资源,其扩张已引发了多方面的生态问题,但是目前关于氮沉降背景下毛竹扩张引起的土壤N_2O和CO_2气体排放变化的研究甚少,且无原位观测数据。采用静态箱-气相色谱法,分析江西庐山毛竹纯林、毛竹扩张形成的毛竹-日本柳杉混交林及日本柳杉纯林3种林分土壤的N_2O和CO_2排放速率和累积排放量及其对模拟氮沉降的响应。结果表明:(1)混交林土壤的NH_4~+-N含量、NO_3~--N含量及pH分别为14.39mg·kg~(-1)、8.65mg·kg~(-1)、4.88,显著高于日本柳杉纯林的9.75 mg·kg~(-1)、5.58 mg·kg~(-1)、4.05,但是混交林土壤DOC含量(236.5 mg·kg~(-1))却显著低于日本柳杉纯林(382.0mg·kg~(-1))。(2)混交林土壤N_2O累积排放量(393.6mg·m~(-2))显著高于毛竹纯林(202.5mg·m~(-2))和日本柳杉纯林(192.8mg·m~(-2)),混交林土壤CO_2累积排放量(4 655 g·m~(-2))显著高于日本柳杉纯林(2 815 g·m~(-2))。(3)模拟氮沉降未对3种林分类型土壤的CO_2排放速率和累积排放量产生显著影响,但明显增加了混交林和日本柳杉纯林的N_2O累积排放量。本研究表明:毛竹扩张不同阶段土壤的理化性质、N_2O及CO_2排放表现出不同特征。毛竹扩张过程中一定程度上增大了土壤N_2O和CO_2的排放量,但是完全扩张后N_2O排放出现明显下降趋势,而CO_2的排放未发生显著变化。同时,氮沉降促进了毛竹未扩张和扩张初期土壤的N_2O排放,而对CO_2排放未产生显著影响。表明在未来气候变化条件下管理亚热带毛竹扩张时,必须明确考虑这些生态系统组成、结构和影响因子之间的影响。 相似文献
2.
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
3.
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
4.
炭输入及生化调控对设施菜田土壤N_2O排放的影响 总被引:1,自引:0,他引:1
本研究以河北永清蔬菜基地设施菜田土壤为研究对象,控制温度(25±1)℃和土壤含水量(70%WFPS),采用静态培养方法,通过监测培养期间土壤N_2O排放通量、无机氮含量及土壤中酶活性的变化情况,研究炭输入及生化调控对设施菜田N_2O排放及氮素转化的影响。结果表明,土壤添加尿素后,N_2O排放峰值达到644.11μg N·kg~(-1)·d~(-1),添加双氰胺(DCD)和石灰氮(CaCN_2)的土壤N_2O排放峰值分别为101.47μg N·kg~(-1)·d~(-1)和36.74μg N·kg~(-1)·d~(-1),对于N_2O减排效果好,且能有效抑制亚硝态氮的产生;施用控释尿素、添加黑炭或有机肥能减少N_2O排放,而添加石灰氮闷棚显著增加了N_2O排放。控释尿素、秸秆、黑炭、DCD和CaCN_2均对铵态氮向硝态氮的转化有一定抑制作用,施加石灰氮或有机肥有助于减少硝态氮向亚硝态氮的转化。相关分析表明,土壤中硝态氮和亚硝态氮含量增加,有助于反硝化过程的进行,增加了N_2O排放的风险。 相似文献
5.
通过室内培养试验研究等氮量下不同施肥次数对N_2O排放的影响。试验设一次性施氮(S1,将200 mg/kg氮肥一次性施入土壤),二次分施(S2,将200 mg/kg氮肥分两次平均施入土壤),三次分施(S3,将200 mg/kg氮肥分80、60、60 mg/kg 3次施入土壤)和空白(CK,不施肥)4个处理。培养在65%田间持水量,30℃恒温箱中进行。结果表明,氮肥施入显著促进土壤N_2O排放;等施氮量下,不同分施次数使土壤pH呈显著性差异,而土壤pH的差异又影响了土壤N_2O累积排放量;分施次数越多,土壤酸化程度越强,N_2O累积排放量越少。因此,在等施氮量下,要充分考虑土壤酸化、N_2O排放、NO–3-N积累以及施肥成本等,确定合理分施次数。 相似文献
6.
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
7.
为合理利用工业副产硫酸铵,探究3,4—二甲基吡唑磷酸盐(DMPP)配施硫酸铵对石灰性褐土中氮素转化及N_2O和CO_2排放的影响。通过室内培养试验,研究不同剂量DMPP与硫酸铵配施后,石灰性褐土中铵态氮(NH_4~+-N)含量、硝态氮(NO_3~--N)含量、土壤pH、N_2O和CO_2排放通量和累计排放量的动态变化,并进行了相关性分析。结果表明:单施硫酸铵的ASN处理在培养的前15天硝化作用强烈,第15天时,土壤NH_4~+-N含量降低了477.28 mg/kg, NO_3~--N含量增高了177.03 mg/kg。添加DMPP可以明显抑制硫酸铵NH_4~+-N向NO_3~--N转化。培养30天后,0.75%~1.75%剂量的DMPP处理的土壤NO_3~--N含量低于ASN处理174.02~177.00 mg/kg,硝化抑制率为94.92%~95.30%,且在0.75%~1.75%浓度范围内未表现出明显的剂量差异效应。各剂量DMPP在试验期间的硝化抑制效果表现较好,其作用时长为30天以上。培养30天时,与空白CKII处理相比,单施硫酸铵T1处理的N_2O和CO_2的累计排放量分别显著增加了975.3%,126.66%(P0.05),而添加了DMPP的T2处理相较于单施硫酸铵T1处理,N_2O和CO_2累计排放量分别显著降低了76.8%,6.22%(P0.05)。相关性分析表明,CO_2排放通量与N_2O排放通量呈正相关关系,土壤pH与N_2O、CO_2排放通量呈负相关关系。硫酸铵与0.75%DMPP配合施用在一定程度上可以抑制土壤酸化,同时短期内可以显著降低N_2O和CO_2累计排放量(P0.05)。 相似文献
8.
有机无机肥配施对玉米-豇豆种植系统土壤N2O排放的影响 总被引:1,自引:0,他引:1
在等施氮量条件下,比较有机肥与无机肥施用后旱地玉米-豇豆复种系统土壤硝化与反硝化作用、N_2O排放与作物产量的变化,有助于正确认识肥料施用对N_2O排放的影响,为制定大田合理的丰产减排措施提供理论依据。本研究通过田间试验,利用静态箱技术和BaPS气压过程分离技术研究了不同肥料类型处理(无机肥、有机肥、有机无机肥配施)下玉米-豇豆种植系统土壤N_2O排放、硝化与反硝化作用的变化特征。结果表明:1)相对于单施无机肥或有机肥,有机无机肥配施可显著降低土壤硝化作用速率;在玉米生长季,有机无机肥配施处理平均土壤硝化作用速率分别比化肥和有机肥处理显著降低了28.74%和13.96%,豇豆生长季显著降低了24.66%和13.28%。土壤反硝化作用速率在各施肥处理间差异不显著。2)有机无机肥配施显著降低土壤N_2O排放;在玉米生长季,有机无机肥配施处理分别比无机肥处理和有机肥处理显著降低33.44%和32.29%,在豇豆生长季分别显著降低27.00%和15.14%。3)相关分析表明,土壤N_2O排放与硝化作用速率呈极显著相关,而与反硝化作用速率呈不显著相关。4)有机无机配施处理玉米和豇豆产量最高。因此,有机无机肥配施能有效降低玉米-豇豆系统土壤N_2O排放和提高作物产量,是一项丰产低N_2O排放的施肥技术,但长期有机无机肥配施对土壤N_2O排放和作物产量的影响还需要进一步研究。 相似文献
9.
施肥处理对春季冻融期灰漠土农田温室气体排放的影响 总被引:1,自引:0,他引:1
绿洲灰漠土冻融交替明显,但缺乏该时期气体通量及动态变化方面的研究。选取NPK(氮磷钾肥)、NPKS(0.9NPK+0.1秸秆氮)、NPKM(1/3NPK+2/3羊粪氮)和NPKM+(1.5倍NPKM)处理作为研究对象,利用静态箱气相色谱法开展2013—2014年春季冻融期温室气体排放观测试验。结果显示,春季冻融期间,有机肥添加处理CO_2排放量较高,其中NPKM+和NPKM处理CO_2平均排放量分别为C 113 mg m~(-2) h~(-1)和85 mg m~(-2) h~(-1),其次为NPKS(72 mg m~(-2) h~(-1))、NPK(75 mg m~(-2) h~(-1))和CK(35 mg m~(-2) h~(-1))。同样,NPKM+和NPKM处理有相对更高的N_2O排放,春冻平均排放通量分别为N 73μg m~(-2) h~(-1)和42μg m~(-2) h~(-1),显著高于NPKS(22μg m~(-2) h~(-1))和NPK(17μg m~(-2) h~(-1))处理(p0.05)。CH_4排放量相对较低,各处理无明显差异(p0.05)。分析发现,N_2O在冻融期呈现先增加后急剧减少的趋势,CO_2变幅不明显。与全年总排放量相比,冻融期(27 d)N_2O的排放量占全年的9%~18%,CH_4冻融期间排放比重占全年排放量的6%~14%。所以,冻融交替期是灰漠土农田温室气体排放的相对高发时期,估算温室气体排放时应充分考虑。 相似文献
10.
稻田固氮对土壤维持肥力有着重要的作用,但水稻种植与固氮菌及其活性之间的关系尚不清楚。本试验利用~(15)N_2直接标记法测定了下位砂姜土发育的简育水耕人为土在种水稻和不种水稻条件下的生物固氮量,及其在土壤不同层次(0~1、1~5、5~15 cm)和水稻中的分配,并通过实时荧光定量PCR技术测定了土壤中固氮菌nifH DNA及RNA基因数量。结果表明:种水稻处理显著提高了土壤各层固氮量,尤其提高了1~5 cm和5~15 cm土层土壤固氮量对总固氮量的贡献;种水稻处理的总固氮量是不种水稻处理的10.3倍;水稻植株中生物固定的氮占总固氮量的31.48%;在0~1 cm土层,种水稻处理显著提高了nifH RNA基因数量,而对nifH DNA基因数量的增加不显著。可见,水稻种植没有增加固氮菌的数量,稻田固氮量的增加是因为水稻种植极大地促进了固氮菌nifH基因的表达,提高了固氮菌的固氮活性。 相似文献
11.
《Communications in Soil Science and Plant Analysis》2012,43(1-2):265-271
This trial was carried out to study the evolution of the nutrient parameters of the nutrient solution applied to tomato plants (Lycopersicum sculentum Mill. Forteza) cultivated in Mediterranean greenhouse conditions under different fertigation management models. The dynamic model is based on soil water content, which was measured by tensiometers, and on soil solutions obtained with suction cups (porous ceramic cup water samplers). The local traditional method consists of following technical recommendations, and the classical model requires the estimation of Crop Factor (Kc) and knowing the nutrient extraction. Nutrient solution and water applied are functions of the fertigation management criteria. The water used for fertigation was classified as C4-S3 according to the Riverside classification system. The cultivation period lasted from 15 August to 20 April. The nutrient parameters studied in nutrient and soil solution were pH, electrical conductivity (EC), nitrate (NO3 ?), phosphate (H2PO4 ?), potassium (K+), calcium (Ca2+), magnesium (Mg2+), sodium (Na+), and chloride (Cl?). The pH shows similar trends under the different treatments. Electrical conductivity is in the range of 2.8–4.5 dS m?1. Chloride, sodium, magnesium, and sulfate are exclusively modified by the salt concentration in the irrigation water, so it can be assumed that the three treatments vary equally. Nitrate, potassium, phosphate, and calcium are modified depending on each fertigation management method. Soil solution is modified by the nutrient solution applied. Dynamic management allows low nutrient concentration in the nutrient solution to be maintained and keeps soil nutrient concentration low, reducing fertilizer losses and therefore aquifer contamination. 相似文献
12.
Respiratory metabolism was investigated by determining the following enzyme activities and nicotinamide nucleotide coenzyme contents in barley shoots (Hordeum vulgare L., var. Akashinriki) during vernalization : glucose-6-phosphate dehydrogenase, phosphoglucoisomerase, enolase, isocitrate dehydrogenase, malate dehydrogenase, and glutamic dehydrogenase. The activities of glucose-6-phosphate de hydrogenase and phosphoglucoisomerase in vernalized shoots were slightly lower than those in non-vernalized samples. Malate dehydrogenase activity increased gradually in vernalized shoots and was always higher than in non-vernalized shoots. Activation was found in enolase, isocitrate dehydrogenase and glutamic dehydrogenase after a long vernalization treatment. The contents of total nicotinamide nucleotide coenzymes increased during the early germination stage in both treatments, then decreased gradually in the succeeding stage. 相似文献
13.
14.
Abstract In a lysimeter study it was found that moderate rates of ammonium nitrate increased utilization percentages in spring wheat, and the leaching was 10% or less of added N. Over-optimal rates reduced utilization percentages and increased leaching to almost 50% of the highest doses. Late split application of calcium nitrate increased the percentage of N in grain. Furthermore, leaching of N was not reduced, but occurred somewhat later in the fall and winter seasons. Leaching of Cl? was more rapid and that of SO4 2- was delayed relative to the leaching of NO3 ?. Rather large negative N balances were obtained, also after over-optimal application rates, and total N content of the soil was reduced. Compared with the N0 treatment, differences in soil N residues amounted to 15–25% of added N in seven years. Gaseous losses had apparently taken place both from the added N and from soil N according to the total-N analysis. 相似文献
15.
J. Juárez-Rodríguez F. Fernández-Luqueño E. Conde V. Reyes-Varela F. Cervantes-Santiago E. Botello-Alvarez 《Journal of plant nutrition》2013,36(4):511-523
Sludge derived from cow manure anaerobically digested to produce biogas (methane; CH4) was applied to maize (Zea mays L.) cultivated in a nutrient-low, alkaline, saline soil with electrolytic conductivity 9.4 dS m?1 and pH 9.3. Carbon dioxide (CO2) emission increased 3.1 times when sludge was applied to soil, 1.6 times when cultivated with maize and 3.5 times in sludge-amended maize cultivated soil compared to the unamended uncultivated soil (1.51 mg C kg?1 soil day?1). Nitrous oxide (N2O) emission from unamended soil was -0.0004 μg nitrogen (N) kg?1 soil day?1 and similar from soil cultivated with maize (0.27 μg N kg?1 soil day?1). Application of sludge increased the N2O emission to 4.59 μg N kg?1 soil day?1, but cultivating this soil reduced it to 2.42 μg N kg?1 soil day?1. It was found that application of anaerobic digested cow manure stimulated maize development in an alkaline saline soil and increased emissions of CO2 and N2O. 相似文献
16.
ABSTRACT A study was carried out to determine the influence of nitrogen (N) sources on the growth, nitrate (NO3 ?) accumulation, and macronutrient concentrations of pakchoi (Brassica chinensis L.) in hydroponics. Plants were supplied with NO3 ? and two amino acids (AA), glutamic acid (Glu), and glutamine (Gln), at six NO3 ?-N/AA-N molar ratios: (1) 100:0, (2) 80:20, (3) 60:40, (4) 40:60, (5) 20:80, (6) 0:100. The total N concentration was 12.5 mmol/L for all treatments in nutrient solutions. Both AAs reduced plant growth with decreasing NO3 ?-N/AA-N ratios, but the reduction was for Gln than for Glu. At 80:20 NO3 ?-N: Gln-N ratio, the Gln had no significant effect on pakchoi fresh weights. Decreasing NO3 ?-N/AA-N ratios reduced NO3 ? concentrations in the plant, regardless of AA sources. Adding an appropriate portion of AA-N to nutrient solutions for hydroponic culture increased concentrations of N, phosphorus (P), and potassium (K) in pakchoi shoots. Substituting 20% or less of NO3 ?-N with Gln-N in hydroponic culture will increase the pakchoi quality by reducing NO3 ? concentration and increasing mineral nutrient concentrations in shoots without significant reduction of crop yields. 相似文献
17.
减氮配施有机物质对土壤氮素淋失的调控作用 总被引:2,自引:1,他引:1
采用室内土柱模拟试验方法,研究不同氮肥施用下1m土体中氮素的分布和移动特征,揭示土壤氮素动态变化规律。结果表明:FN(农民习惯施无机氮用量)、RN(根据土壤养分供应和作物需求确定的推荐无机氮用量)显著增加了土壤上层NH_4^+-N和NO_3^--N向下层淋失。RN+HA(与推荐无机氮纯养分相等的锌腐酸尿素)和RN40%+OMB(推荐无机氮肥减60%基础上配施自制有机调理物质)可延长上层土壤NH_4^+-N峰值出现时间,降低下层NH_4^+-N。淋溶结束后,等氮量下增施HA较RN降低60cm以下NH_4^+-N残留29.7%~54.2%;降低60—80cm NO_3^--N累积17.4%。RN40%+OMB处理无机氮肥用量最小,0—20cm的NH_4^+-N最高,40—100cm稳定在2.0mg/kg左右;0—20,20—40cm土层NO_3^--N较RN+HA增加12.3%和2.0%,显著降低40cm以下NO_3^--N残留。RN+HA和RN40%+OMB较RN的土壤总无机氮残留分别减少7.4%和20.2%,降低表观淋失率。因此,RN40%+OMB可较好地抑制氮素下移,降低氮素淋失风险,为减少氮素淋失、明确合理氮肥施用方式提供科学依据。 相似文献
19.
不同形态氮对掌叶半夏生长及块茎主要化学成分影响研究 总被引:3,自引:1,他引:2
【目的】本文利用盆栽试验,探讨了不同铵态氮、 硝态氮供应比例对掌叶半夏生长、 相关生理指标及块茎中主要活性成分含量的影响,以期为掌叶半夏的合理施肥、 科学种植提供技术依据。【方法】盆栽试验以蛭石为栽培基质,以掌叶半夏为试验材料,采用不同铵态氮、 硝态氮比例处理,分析不同铵硝比例处理下掌叶半夏叶片中抗氧化保护酶(SOD、 CAT), 叶片、 块茎中氮代谢关键酶(NR)的活性及块茎中次生代谢产物(MDA、 硝酸盐及主要活性成分)的含量变化。【结果】 1)叶片鲜重、 块茎鲜重及总叶绿素含量总体均随铵态氮比例的升高而呈逐渐增加趋势,其中在全铵营养下,块茎鲜重和总叶绿素含量均达到最高值。2)随着铵态氮比例的升高,植株叶片中SOD、 CAT酶活性呈先升高后降低趋势; 当铵硝比为50∶50时,SOD、 CAT酶活性最高,此时,叶片中NO-3-N含量也达到最高。3)在全铵营养或全硝营养下,MDA含量均高于其他处理; 当铵硝比为50∶50时,MDA累积量最低。4)在全硝营养下,叶片、 块茎中的NR活性均达到最高值,同处理水平下叶片中NR活性要高于块茎; 并且随着铵态氮比例的增加叶片中NR活性呈逐渐降低的趋势,而块茎中的NR活性则呈逐渐增加的趋势。5)块茎中主要活性成分的累积更依赖于两种氮素的配施作用,在较高的铵态氮配施处理下(75∶25时),总生物碱、 总有机酸及腺苷的积累量均取得最高值。【结论】适宜比例的铵硝配比可以促进掌叶半夏生长及产量的形成,其促进效果也显著高于全硝营养; 当铵硝比为50∶50时,其植物体内的相关酶活性也达到最高,说明适宜的铵硝配比能减轻膜质过氧化对植株细胞膜造成的损伤; 同时,较高的NH+4-N也有利于块茎中主要活性成分的积累,尤以铵硝比为75∶25时,累积效果最显著。 相似文献
20.
《Journal of plant nutrition》2013,36(6):1277-1286
Abstract Male and female leaf discs of Jojoba [Simmondsia chinensis (Link) Schneider] were cultured on Murashige and Skoog (MS) media supplemented with various nitrate:ammonium ratio and phytohormones concentrations. For the optimum callus growth, hormonal concentrations were remained equal for both male and female leaf tissues i.e., 0.4 mg L?1 2,4‐dichlorophenoxyaceticacid, 1.25 mg L?1 6‐benzyladenine and 0.5 mgL?1 kinetin. However, a statistically significant difference was observed when Murashige and Skoog media was supplemented with an additional nitrogen source. In female leaf tissue, maximum fresh and dry weights were recorded in Murashige and Skoog media supplemented with an additional source of NO3 ?:NH4 + (60 mM) whereas in male leaf tissue this addition was inhibitory. This study suggests that nitrogen requirement may be different for optimum callus growth in both male and female leaf tissues. 相似文献