Dissolved organic carbon and nitrogen in precipitation, throughfall and stemflow from Schima superba and Cunninghamia lanceolata plantations in subtropical China

Despite growing attention to the role of dissolved organic carbon (DOC) and dissolved organic nitrogen (DON) in forest nutrient cycling, their monthly concentration dynamics in forest ecosystems, especially in subtropical forests only were little known. The goal of this study is to measure the concentrations and monthly dynamics of DOC and DON in precipitation, throughfall and stemflow for two planta- tions of Schima superba (SS) and Chinese fir (Cunninghamia lanceolata, CF) in Jianou, Fujian, China. Samples of precipitation, throughfall and stemflow were collected on a rain event base from January 2002 to December 2002. Upon collection, all water samples were analyzed for DOC, NO3 -N, NH4 -N and total dissolved N (TDN). DON was calculated by subtracting NO3 -N and NH4 -N from TDN. The results - + - + showed that the precipitation had a mean DOC concentration of 1.7 mg·L-1 and DON concentration of 0.13 mg·L-1. The mean DOC and DON concentrations in throughfall were 11.2 and 0.24 mg·L-1 in the SS and 10.3 and 0.19 mg·L-1 in the CF respectively. Stemflow DOC and DON concentrations in the CF (19.1 and 0.66 mg·L-1 respectively) were significantly higher than those in the SS (17.6 and 0.48 mg·L-1 respectively). No clear monthly variation in precipitation DOC concentration was found in our study, while DON concentration in precipita- tion tended to be higher in summer or autumn. The monthly variations of DON concentrations were very similar in throughfall and stemflow at both forests, showing an increase at the beginning of the rainy season in March. In contrast, monthly changes of the DOC concentrations in throughfall of the SS and CF were different to those in stemflow. Throughfall DOC concentrations were higher from February to April, while relatively higher DOC concentrations in stemflow were found during September-November period.

Labile and stabile soil organic carbon fractions in surface horizons of mountain soils–relationships with vegetation and altitude

Global and local climate changes could disturb carbon sequestration and carbon stocks in forest soils. Thus, it is important to characterize the stability of soil organic matter and the dynamics of soil organic carbon(SOC) fractions in forest ecosystems. This study had two aims:(1) to evaluate the effects of altitude and vegetation on the content of labile and stabile forms of organic carbon in the mountain soils; and(2) to assess the impact of the properties of soil organic matter on the SOC pools under changing environmental conditions. The studies were conducted in the Karkonosze Mountains(SW Poland, Central Europe). The content of the most labile fraction of carbon(dissolved organic carbon,DOC) decreases with altitude, but the content of fulvic acids(FA), clearly increases in the zone above 1000 m asl, while the stabile fraction(humins, nonhydrolyzing carbon) significantly decreases. A higher contribution of stabile forms was found in soils under coniferous forests(Norway spruce), while a smaller-under deciduous forests(European beech) and on grasslands. The expected climate change and the ongoing land use transformations in the zone above1000 m asl may lead to a substantial increase in the stable humus fraction(mainly of a non-hydrolyzing carbon) and an increase in the SOC pools, even if humus acids are characterized by a lower maturity and greater mobility favorable to soil podzolization.In the lower zone(below 1000 m asl), a decrease in the most stable humus forms can be expected,accompanied by an increase of DOC contribution,which will result in a reduction in SOC pools. Overall,the expected prevailing(spatial) effect is a decreasing contribution of the most stable humus fractions,which will be associated with a reduction in the SOC pools in medium-high mountains of temperate zone of Central Europe.

Effect of Different Fertilization Patterns on Carbon and Nitrogen Components of Tobacco Topsoil

In order to explore the fertilizing ways and dynamic changes of soil carbon and nitrogen in the main producing areas of tobacco in Guizhou,research was conducted to study the variations of dissolved organic carbon and nitrogen,total organic carbon and nitrogen and their ratio of tobacco-topsoil in organic fertilization pattern and conventional cultivation pattern （No fertilizer as control） by pot experiment.The results were as follows：（1） The effects of different fertilization patterns on soil dissolved organic carbon and nitrogen and total organic carbon and nitrogen were significantly different.The content of DOC,DON,TOC and TON in tobaccotopsoil was decreased with the advancing of growth period in conventional fertilization pattern.In the conventional fertilization pattern,the accumulation of DOC and TOC was increased first and then decreased,and the accumulation of DON and TON was decreased first and then increased.（2） The TOC content at the different growing stage and DOC content at the middle and later stage of tobacco were significantly improved in organic fertilization patterns.The accumulation of DON and TON in the conventional fertilization pattern was significantly higher than those in the organic fertilizer pattern and control at the rosette stage and vigorous stage.In the harvest period,the content of DOC,DON,TOC and TON of tobacco-topsoil in the conventional fertilization and organic fertilization pattern was significantly higher than those in the control.（3）The DOC/DON ratio and the TOC/TiON ratio was increased gradually with the advancing of growth period in conventional fertilization pattern,but they were increased first and then decreased in the organic fertilization pattern and CK.The DOC/DON and TOC/TON ratio of tobacco-topsoil in different fertilization patterns was showed as Y J＞ CK＞ CG at the different growing stage.The experiment results revealed that：The organic fertilization pattern may improve significantly the accumulation of DOC,DON,TOC and TON of tobacco-topsoil at the middle and later stage and the DOC/DON and TOC/TON ratio at the different growth stage.It contributed to the continuous and balanced supply of nutrients at the middle and later stage of tobacco and the soil fertility.

Concentration,sources and wet deposition of dissolved nitrogen and organic carbon in the Northern Indo-Gangetic Plain during monsoon

Precipitation represents an important phenomenon for carbon and nitrogen deposition.Here,the concentrations and fluxes of dissolved organic carbon(DOC)and total dissolved nitrogen(TDN)with their potential sources were analyzed in wet precipitation during summer monsoon from the Northern Indo-Gangetic Plain(IGP),important but neglected area.The volume-weighted mean(VWM)concentration of DOC and TDN were 687.04 and 1210.23μg/L,respectively.Similarly,the VWM concentration of major ions were in a sequence of NH_(4)^(+)>Ca^(2+)>SO_(4)^(2-)>Na^(+)>K^(+)>NO_(3)~->Cl~->Mg^(2+)>F~->NO_(2)~-,suggesting NH_(4)^(+)and Ca^(2+)from agricultural activities and crustal dust played a vital role in precipitation chemistry.Moreover,the wet deposition flux of DOC and TDN were 9.95 and 17.06 kg/(ha year),respectively.The wet deposition flux of inorganic nitrogen species such as NH_(4)^(+)-N and NO_(3)^(-)-N were 14.31 and 0.47 kg/(ha year),respectively,demonstrating the strong influence of emission sources and precipitation volume.Source attribution from different analysis suggested the influence of biomass burning on DOC and anthropogenic activities(agriculture,animal husbandry)on nitrogenous species.The air-mass back trajectory analysis indicated the influence of air masses originating from the Bay of Bengal,which possibly carried marine and anthropogenic pollutants along with the biomass burning emissions to the sampling site.This study bridges the data gap in the less studied part of the northern IGP region and provides new information for policy makers to deal with pollution control.

Effects of Carbon and Nitrogen Additions on Soil Microbial Biomass Carbon and Enzyme Activities Under Rice Straw Returning

The effects of different amounts of carbon and nitrogen sources on the soil microbial biomass carbon,dissolved organic carbon and related enzyme activities were studied by the simulation experiment of rice straw returning to the field,and the mechanism of the decomposition of rice straw returning to the field was discussed.Completely randomized experiment of the two factors of the three levels was designed,and a total of nine treatments of indoor soil incubation tests were conducted.Full amount of rice straw was applied to the soil in this simulation experiment and different amounts of brown sugar and urea were added in the three levels of 0(no carbon source and nitrogen source),1(low levels of carbon and nitrogen sources)and 2(high levels of carbon and nitrogen sources),respectively.The results showed that the addition of different amounts of carbon and nitrogen sources to the rice straw could increase the soil carbon content.Compared with T0N0,the microbial biomass carbon of T2N2 was increased significantly by 170.48%;the dissolved organic carbon content of T1N2 was significantly increased by 58.14%and the free humic acid carbon contents of T0N2,T1N1 and T2N0 were significantly increased by 56.16%and 45.55%and 47.80%,respectively;however,there were no significant differences among those of treatments at later incubation periods.The addition of different carbon and nitrogen sources could promote the soil enzyme activities.During the incubation period,all of the soil enzyme activities of adding sugar and urea were higher than those of T0N0 treatment.Therefore,the addition of different amounts of carbon and nitrogen sources to rice straw returning could improve soil microbial biomass carbon content,dissolved organic carbon and soil enzyme activities.

Non-climate environmental factors matter to Holocene dynamics of soil organic carbon and nitrogen in an alpine permafrost wetland,Qinghai‒Tibet Plateau

Studies on the responses of soil organic carbon(SOC)and nitrogen dynamics to Holocene climate and environment in permafrost peatlands and/or wetlands might serve as analogues for future scenarios,and they can help predict the fate of the frozen SOC and nitrogen under a warming climate.To date,little is known about these issues on the Qinghai‒Tibet Plateau(QTP).Here,we investigated the accumulations of SOC and nitrogen in a permafrost wetland on the northeastern QTP,and analyzed their links with Holocene climatic and environmental changes.In order to do so,we studied grain size,soil organic matter,SOC,and nitrogen contents,bulk density,geochemical parameters,and the accelerator mass spectrometry(AMS)^(14)C dating of the 216-cm-deep wetland profile.SOC and nitrogen contents revealed a general uptrend over last 7300 years.SOC stocks for depths of 0-100 and 0-200 cm were 50.1 and 79.0 kgC m^(-2),respectively,and nitrogen stocks for the same depths were 4.3 and 6.6 kgN m^(-2),respectively.Overall,a cooling and drying trend for regional climate over last 7300 years was inferred from the declining chemical weathering and humidity index.Meanwhile,SOC and nitrogen accumulated rapidly in 1110e720 BP,while apparent accumulation rates of SOC and nitrogen were much lower during the other periods of the last 7300 years.Consequently,we proposed a probable conceptual framework for the concordant development of syngenetic permafrost and SOC and nitrogen accumulations in alpine permafrost wetlands.This indicates that,apart from controls of climate,non-climate environmental factors,such as dust deposition and site hydrology,matter to SOC and nitrogen accumulations in permafrost wetlands.We emphasized that environmental changes driven by climate change have important impacts on SOC and nitrogen accumulations in alpine permafrost wetlands.This study could provide data support for regional and global estimates of SOC and nitrogen pools and for global models on carbon‒climate interactions that take into account of alpine permafrost wetlands on the northeastern QTP at mid-latitudes.

配施紫云英对不同类型水稻土溶解性有机碳氮淋溶及损失的影响

为探讨配施紫云英对不同类型稻田土壤溶解性有机碳(Dissolved organic carbon,DOC)和溶解性有机氮(Dissolved organic nitrogen,DON)含量的影响程度,阐明稻田土壤DOC和DON的淋溶特性,本研究以亚热带3种典型水稻土(黄泥田、灰黄泥田和灰泥田)为研究对象,通过田间试验,探讨等氮磷钾条件下单施化肥(CK)和紫云英配施化肥(cmv)处理对不同水稻土DOC和DON的动态变化、淋溶特性及损失的影响。结果表明,不同土壤类型水稻土DOC和DON的淋溶特性有所不同。3种供试水稻土中,灰泥田水稻土DOC淋溶损失量最大,其CK处理DOC淋溶损失量较灰黄泥田和黄泥田分别显著提高24.09%和72.15%,cmv处理淋溶损失量较灰黄泥田和黄泥田分别显著提高16.53%和40.55%;而黄泥田水稻土DON淋溶损失量最大,其CK处理淋溶损失量较灰黄泥田和灰泥田分别显著提高18.93%和37.01%,cmv处理3种不同类型水稻土DON淋溶损失量无显著差异。配施紫云英可显著降低水稻土DON的淋溶损失量,每季水稻中cmv处理黄泥田、灰黄泥田和灰泥田DON淋溶损失量较CK处理分别降低了24.67%、14.88%和13.54%;黄泥田cmv处理DOC较CK处理提高了19.19%,而灰黄泥田和灰泥田2种施肥处理无显著差异。供试稻田中DOC和DON在土层间的淋溶具有一定的延迟性,且DOC的延迟时间大于DON。灰色关联分析表明,在土壤性质中有机质是影响水稻土DOC淋溶损失的重要因素,孔隙度是DON淋溶损失的重要影响因素。不同类型水稻土DON的淋失早于DOC,且DON在黄泥田中淋溶损失较高,而DOC在灰泥田中淋溶损失较高;在等氮磷钾的条件下,配施紫云英可减少水稻土DON的淋溶损失,而低肥力水稻土DOC的淋溶损失量有所增加。

东北地区典型湖沼沉积物溶解态有机质组成特征及来源解析:以库里泡为例

溶解态有机质(DOM)是湖泊沉积物的重要组分,解析DOM的组成和来源对于深入理解湖泊有机质生物地球化学循环及控制水体富营养化具有重要意义。本研究于2021年5月和8月采集了大庆市库里泡表层及柱状沉积物、泡内水生物(浮游藻类、挺水植物和沉水植物)、岸边土壤、陆生C3和C4植物、禽畜粪便以及城镇污水等样品,分析了样品DOM的稳定同位素(δ^(13)C和δ^(15)N)组成及三维荧光光谱特征,并利用IsoSource软件计算了不同来源样品对沉积物DOM的贡献率。结果显示:(1)库里泡内表层沉积物DOM的δ13C和δ15N组成存在季节性差异,5月δ^(13)C和δ^(15)N均值分别为-25.54‰和9.02‰,8月分别为-26.81‰和8.40‰。(2)库里泡内柱状沉积物DOM的δ^(13)C和δ^(15)N组成在垂直方向存在差异,表层(0~3 cm)δ^(13)C和δ^(15)N均值分别为-26.58‰和9.04‰,深层(3~30 cm)均值分别为-25.40‰和10.61‰。(3)表层沉积物DOM的三维荧光组分存在季节性差异。5月以类腐殖质荧光组分为主,占比为87.89%,HIX和BIX分别为6.27和0.67;8月蛋白类荧光组分占比为49.58%,HIX和BIX指数均值分别为1.72和0.87。(4)5月表层沉积物DOM外源输入占比为61%,以土壤(21.40%)和城镇污水(18.08%)为主;而8月内源贡献占比稍高(55.10%),且以挺水植物为主(48.68%)。(5)柱状沉积物(0~30 cm)不同深度DOM来源组成相近,主要为城镇污水、沉水植物/藻和挺水植物,贡献率均值分别为42.13%、25.07%和18.53%。整体上,库里泡沉积物DOM来源主要受到流域内人类活动及气候特征的影响,本文研究结果有利于加深对我国东北地区湖泊沉积物有机质迁移转化及累积规律的认识。

增温对亚热带常绿阔叶林凋落物溶解性有机质的影响

为了解增温对凋落物分解的影响,依托亚热带常绿阔叶林野外增温试验平台,收集林内凋落物分别布设于对照和增温(+4℃)小区中,对增温下凋落物分解过程中可溶性有机质数量和光谱特征的变化进行研究。结果表明,凋落物质量残留率随分解时间的增加显著下降,在0~60 d内快速下降了20.08%~23.32%,在60~210 d内缓慢下降了6.35%~10.98%。凋落物源可溶性有机碳含量随分解时间增加呈现先快后慢的下降趋势,整体降低了94.15%;可溶性有机氮含量则波动式降低了81.82%;可溶性有机质的光谱特征(SUVA254、SUVA260、SUVA280和SUVA370)呈增加-下降-增加的趋势。增温未显著影响凋落物质量残留率和可溶性有机质的光谱特征,但可溶性有机碳和有机氮的含量降低了16.72%和25.10%。凋落物分解降低了凋落物质量残留率和可溶性有机碳、有机氮含量,改变了可溶性有机质光谱特征;增温虽然降低了凋落物可溶性有机碳、有机氮含量,但未显著改变凋落物质量残留率和可溶性有机质光谱特征。

秸秆还田下氮肥水平对秸秆碳固定及土壤有机碳储量的影响

土壤有机碳(SOC)库在养分循环和缓解全球温室效应方面起重要作用。为了探究氮肥对秸秆碳在土壤中的转化以及SOC库的影响,本研究采用盆栽试验,向不同施氮水平[0 kg(N)∙hm^(-2)(N0)、120 kg(N)∙hm^(-2)(N120)、240 kg(N)∙hm^(-2)(N240)、360 kg(N)∙hm^(-2)(N360)]的稻田土壤中添加^(13)C标记的小麦秸秆,在水稻成熟后采集土样测定不同碳组分含量以及δ^(13)C值,并分析土壤微生物群落组成。研究结果显示,与N0处理相比,N240和N360处理中SOC显著提高7.8%和7.4%,全氮显著提高37.2%和34.3%,溶解性有机碳显著提高33.7%和48.6%,微生物量碳显著提高97.9%和89.6%;但土壤碳氮比显著降低21.6%和20.0%。相比N0处理,N120处理的SOC、全氮、碳氮比和溶解性有机碳并没有显著差异,但显著提高微生物量碳的含量。此外,秸秆还田条件下施用氮肥使细菌含量显著提高24.7%~55.4%,真菌含量显著提高18.3%~30.2%,总磷脂脂肪酸含量显著提高18.1%~45.2%。施用氮肥提高>2000μm和250~2000μm团聚体的占比以及游离态颗粒有机碳(fPOC)和微团聚内颗粒有机碳(iPOC)组分的有机碳储量,同时分别显著增加了fPOC和iPOC组分中δ^(13)C值128.3%~194.8%和105.6%~216.9%。但是在高氮(N360)处理下,除fPOC组分外,其他各有机碳组分储量未持续增加。结构方程表明,施用氮肥可通过增加溶解性有机碳含量,增加土壤中fPOC组分中有机碳储量,或者促进微生物群落活性增加iPOC组分中有机碳储量来提高SOC含量。本研究结果表明,秸秆还田条件下施用适量氮肥能够促进秸秆碳在土壤中的固定并且增加SOC含量。

氮添加对森林土壤有机碳库固存及CO_(2)排放的影响研究进展

氮添加会引起土壤理化性质和养分有效性的改变。受此影响,森林植物的地上碳同化能力和地下碳分配格局也会相应地发生变化,总体表现为促进植物生长固碳,增加凋落物和植物根系沉积碳输入土壤,并改变上述植物源有机质的数量和化学成分。与此同时,土壤微生物的群落结构和生态功能也会受到氮添加的影响,由于土壤中的有机碳分解、转化和稳定等过程均受到微生物的驱动,因此,氮添加所引起的底物供应差异和微生物响应会影响森林土壤有机碳的矿化,并最终影响森林土壤有机碳库固存、稳定和CO_(2)排放。但目前关于氮添加对森林土壤有机碳库固存能力和CO_(2)排放特征的影响机制仍不清楚,为此,以森林土壤的碳循环过程为线索,综述了氮添加对底物供应、土壤有机碳激发效应、微生物碳代谢等过程的影响,并尝试梳理在氮添加影响下森林土壤有机碳分解、转化和稳定的微生物驱动机制。这有助于预测氮添加对森林土壤“氮促碳汇”的实际效果,以便研究人员在未来氮沉降日益严重背景下更好地预测森林土壤的碳循环特征,寻找提高森林土壤有机碳库固存能力和降低CO_(2)排放相关途径提供参考。同时,还分析了目前相关研究中存在的问题,并对该领域未来的研究热点进行了展望。

秸秆还田和水旱轮作模式对稻季土壤温室气体排放的影响

【目的】探究不同水旱轮作模式下,冬季作物秸秆还田对后茬水稻季作物产量和温室气体排放的影响,为长江中游稻田选择适宜的秸秆还田方式和农业可持续生产提供科学依据。【方法】田间试验在湖北荆州进行,设置水稻–小麦(稻麦)、水稻–油菜(稻油)和水稻–紫云英(稻肥)3种水旱轮作模式,每个模式下设置冬季作物收获后秸秆还田和不还田处理。在秸秆还田后的水稻季,采用静态暗箱—气相色谱法连续监测稻田中甲烷(CH_(4))和氧化亚氮(N_(2)O)排放量,在水稻分蘖期、抽穗期、成熟期采集0—5、5—10、10—20 cm土层样品,测定微生物量碳(MBC)、可溶性有机碳(DOC)、铵态氮(NH_(4)^(+)-N)和硝态氮(NO_(3)^(-)-N)含量,收获期测定水稻产量。【结果】秸秆还田和不同轮作模式对后茬水稻产量均无显著影响。与稻肥轮作相比,在秸秆还田条件下稻油和稻麦轮作水稻季土壤CH_(4)和N_(2)O排放分别高出44%~58%和17%~30%,在秸秆不还田条件下则分别高出58%~72%和15%~22%。与秸秆不还田相比,秸秆还田条件下3种轮作模式平均CH_(4)和N_(2)O排放分别增加26%~39%和20%~29%。秸秆还田条件下,稻油和稻麦轮作稻季土壤全球增温潜势(GWP)和温室气体排放强度(GHGI)分别比稻肥轮作高出14%~19%和12%~19%,秸秆不还田条件下分别高出18%~23%和15%~24%。与秸秆不还田相比,秸秆还田条件下3种轮作模式稻季土壤平均GWP和GHGI高出31%和32%,同时土壤硝态氮、微生物量碳和可溶性有机碳含量均显著提高。此外,稻麦轮作土壤微生物量碳和可溶性有机碳含量显著高于稻肥、稻油轮作。相关性分析表明,秸秆还田条件下,CH_(4)和N_(2)O排放与NO_(3)^(-)-N呈极显著正相关(P<0.01),而秸秆不还田条件下CH_(4)排放与NO_(3)^(-)-N呈极显著正相关(P<0.01),N_(2)O排放与NH_(4)^(+)-N呈极显著正相关(P<0.01)。【结论】水稻季土壤CH_(4)和N_(2)O的排放与土壤可利用性碳氮浓度的升高密切相关。前茬作物秸秆还田导致水稻季温室气体排放显著增加,与稻麦、稻油轮作相比,水稻–紫云英轮作稻季土壤的温室气体排放量最低,是较为生态环境友好型的种植制度。

Effect of nitrogen addition on DOC leaching and chemical exchanges on canopy leaves in Guangdong Province, China

The impact of nitrogen(N)deposition on dissolved organic carbon(DOC)fractions in throughfall is not well understood.We performed a laboratory experiment and compared DOC leaching from canopy leaves after dipping leaves in pure water(control)and NH4NO3 solution(N-treatment)for 18 h.Net changes of DOC,NH4^+,NO3^-,SO4^2-,K^+,Mg^2+,Ca^2+and H^+contents after dipping leaves were determined by comparing solutions with and without leaves.We recorded no differences of DOC leaching between control and N-treatment,implying that N deposition had minor impacts on canopy DOC production.This confirmed that previous experiments testing the effects of N addition on DOC dynamics without considering the effects of the canopy reaction successfully described the real situation.We also confirmed the previously-reported canopy exchange process in spite of a high background N deposition at our study site.N-treatment significantly increased base cation leaching,especially K^+,and the increase was positively correlated with foliar NH4?retention.Net leaching of H^+and SO4^2-was not affected by the N-treatment.

Short-term Effects of Nitrogen Deposition on Soil Physical and Chemical Properties of Tibetan Forest-Grassland Landscape Boundary

[Objective] The paper was to study the effects of nitrogen deposition on soil nutrients and soil dissolved organic carbon in forest-grassland landscape in Linzhi, Tibet, and to provide scientific basis and basic data for understanding and assessing the effect of atmospheric nitrogen deposition on soil nutrients and soil dissolved organic carbon. [Method] From July 2014 to August 2015, in situ nitrogen deposition （CK0 kg· hm^2/a, LN25 kg·hm^2/a, MN 50 kg·hm^2/a, HN 150 kg· hm^2/a） was simulated in the forestgrassland boundary of Zhuqudeng village, Bujiu Township, LinzhiCounty, Tibet. The soil samples were collected for analyzing nutrient and dissolved contents in the soil layer of 0-20 and 20-40 cm. The effects ofdifferent nitrogen deposition levels on soil nutrients and dissolved organic carbon （DOC） were studied. [Result] Nitrogen deposition had significantimpacts on soil organic matter, total N, total P, total K, available N, available P, available K, exchangeable Ca, exchangeable Mg, pH, and DOC（P〈0.05）. （2） With the deepening of nitrogen deposition from CK, LN, MN to HN in the 0-20 cm boundary soil, the contents of organic matter, total N,total P, available P, exchangeable Ca, exchangeable Mg and DOC kept decreasing, and the content of total K and available N increased continuously. The pH increased in LN treatment and decreased in HN treatment, while the available K content was decreased in LN and HN treatment, butincreased in MN treatment. （3） The contents of organic matter, total N, total P, available N, available P, exchangeable Ca, exchangeable Mg andDOC all decreased at the soil layer of 20-40 cm under the same nitrogen deposition. The pH increased in LN treatment, but decreased in HN treatment; the content of total K decreased in LN treatment and increased in MN and HN treatments; the content of available K decreased in LN andHN treatments, but increased in MN treatment. （4） With the deepening of boundary soil layer （0-20 to 20-40 cm）, the organic matter, total N, totalP, available P, available K, exchangeable Ca, exchangeable Mg, DOC showed the same response to simulated nitrogen deposition, while the available N and total K responded differently. [Conclusion] Different levels of N deposition had certain impact on soil nutrient, and the variation of soilnutrients was not the same at different levels.

Seasonal Variability of Soil Organic Carbon Fractions Under Arable Land

Carbon fractions in soils apparently vary not only in space, but also over time. A lack of knowledge on the seasonal variability of labile carbon fractions under arable land hampers the reliability and comparability of soil organic carbon(SOC) surveys from different studies. Therefore, we studied the seasonal variability of two SOC fractions, particulate organic matter(POM) and dissolved organic carbon(DOC), under maize cropping: POM was determined as the SOC content in particle-size fractions, and DOC was measured as the water-extractable SOC(WESOC) of air-dried soil. Ammonium, nitrate, and water-extractable nitrogen were measured as potential regulating factors of WESOC formation because carbon and nitrogen cycles in soils are strongly connected. There was a significant annual variation of WESOC(coefficient of variation(CV) = 30%). Temporal variations of SOC in particle-size fractions were smaller than those of WESOC. The stocks of SOC in particle-size fractions decreased with decreasing particle sizes, exhibiting a CV of 20%for the coarse sand-size fraction(250–2 000 μm), of 9% for the fine sand-size fraction(50–250 μm), and of 5% for the silt-size fraction(20–50 μm). The WESOC and SOC in particle-size fractions both peaked in March and reached the minimum in May/June and August, respectively. These results indicate the importance of the time of soil sampling during the course of a year, especially when investigating WESOC.

Subtropical urban turfs： Carbon and nitrogen pools and the role of enzyme activity

Urban grasslands not only provide a recreational venue for urban residents, but also sequester organic carbon in vegetation and soils through photosynthesis, and release carbon dioxide through respiration, which largely contribute to carbon storage and fluxes at regional and global scales. We investigated organic carbon and nitrogen pools in subtropical turfs and found that dissolved organic carbon（DOC） and dissolved organic nitrogen（DON）were regulated by several factors including microbial activity which is indicated by soil enzymatic activity. We observed a vertical variation and different temporal patterns in both soil DOC, DON and enzyme activities, which decreased significantly with increasing soil depths. We further found that concentration of soil DON was linked with turf age. There were correlations between grass biomass and soil properties, and soil enzyme activities. In particular, soil bulk density was significantly correlated with soil moisture and soil organic carbon（SOC）. In addition, DOC correlated significantly with DON. Significant negative correlations were also observed between soil total dissolved nitrogen（TDN） and grass biomass of Axonopus compressus and Zoysia matrella. Specifically, grass biomass was significantly correlated with the soil activity of urease and β-glucosidase. Soil NO3-N concentration also showed negative correlations with the activity of both β-glucosidase and protease but there were no significant correlations between cellulase and soil properties or grass biomass. Our study demonstrated a relationship between soil C and N dynamics and soil enzymes that could be modulated to enhance SOC pools through management and maintenance practices.

冻融对湿地土壤可溶性碳、氮和氮矿化的影响

通过室内模拟试验,研究了不同冻融循环过程(-5—5℃或-25—5℃)对沼泽湿地土壤可溶性有机碳(DOC)、可溶性有机氮(DON)以及土壤有机氮矿化过程的影响。结果表明,随着冻融次数的增加,土壤DOC和DON含量呈先增加后降低趋势,土壤DOC含量在冻融1次(-5—5℃或-25—5℃冻融循环处理)后达最大值,而土壤DON分别在冻融2次(-5—5℃冻融循环处理)和4次(-25—5℃冻融循环处理)后达最大值。这说明在短期内冻融交替对土壤DOC和DON含量的影响较明显。冻结温度和冻融次数显著影响土壤有机氮矿化过程,且-25—5℃冻融循环比-5—5℃冻融循环矿化累积量高。冻融循环促进了土壤有机氮的矿化,有利于土壤有效氮的累积,为春季植物生长提供足够的氮素,对维持湿地生态系统稳定具有重要意义。

森林生态系统DOM的来源、特性及流动

可溶性有机物质 (Dissolved Organic Matter)是森林生态系统主要的可移动碳库及重要的养分库。系统综述了森林生态系统 DOM的来源、组成、性质、季节动态 ;DOM释放与存留机制及影响因素 ;森林生态系统 DOM的流动及干扰对 DOM动态影响等。已有研究表明 DOM在森林生态系统 C、N、P循环、成土作用、污染物迁移等方面起着重要作用。今后森林生态系统 DOM的研究应集中于以下几方面 :(1 )确定森林生态系统中 DOM源和汇 ;(2 )评价森林水文条件对 DOM释放与存留的调节作用 ;(3)探讨全球气候变化对森林生态系统 DOM的影响 ;(4)可溶性有机氮 (Dissolved Organic Nitrogen)、可溶性有机磷 (DissolvedOrganic Phosphorus)动态与可溶性有机碳 (Dissolved Organic Carbon)动态的差别。

秸秆还田对稻田土壤溶液中溶解性有机质的影响

研究了麦秆不同方式还田、施用无机氮肥及不同移栽时间对水稻田土壤溶液中溶解性有机碳(DOC)、溶解性有机氮(DON)浓度的影响。结果表明,淹水后土壤溶液中DOC浓度在淹水初期明显增加,而后逐渐下降。添加麦秆这一有机物料,在水稻生长期前2个月内显著提高了DOC,对DON在一段时间内也表现出促进作用,其后差异不显著。施用无机氮肥降低了土壤溶液中DOC、DON浓度。DON的浓度与施肥量呈负相关。水稻推迟移栽,土壤溶液中溶解性有机质(DOM)均显著降低。

有机物料输入稻田提高土壤微生物碳氮及可溶性有机碳氮

土壤微生物量碳、氮和可溶性有机碳、氮是土壤碳、氮库中最活跃的组分,是反应土壤被干扰程度的重要灵敏性指标,通过设置相同有机碳施用量下不同有机物料处理的田间试验,研究了有机物料添加下土壤微生物量碳(soil microbial biomass carbon,MBC)、氮(soil microbial biomass nitrogen,MBN)和可溶性有机碳(dissolved organic carbon,DOC)、氮(dissolved organic nitrogen,DON)的变化特征及相互关系。结果表明化肥和生物碳、玉米秸秆、鲜牛粪或松针配施下土壤微生物量碳、氮和可溶性有机碳、氮显著大于不施肥处理(no fertilization,CK)和单施化肥处理,分别比不施肥处理和单施化肥平均高23.52%和12.66%(MBC)、42.68%和24.02%(MBN)、14.70%和9.99%(DOC)、22.32%和21.79%(DON)。化肥和有机物料配施处理中,化肥+鲜牛粪处理的微生物量碳、氮和可溶性有机碳、氮最高,比CK高26.20%(MBC)、49.54%(MBN)、19.29%(DOC)和32.81%(DON),其次是化肥+生物碳或化肥+玉米秸秆处理,而化肥+松针处理最低。土壤可溶性有机碳质量分数(308.87 mg/kg)小于微生物量碳(474.71 mg/kg),而可溶性有机氮质量分数(53.07 mg/kg)要大于微生物量氮(34.79 mg/kg)。与不施肥处理相比,化肥和有机物料配施显著降低MBC/MBN和DOC/DON,降低率分别为24.57%和7.71%。MBC和DOC、MBN和DON随着土壤有机碳(soil organic carbon,SOC)、全氮(total nitrogen,TN)的增加呈显著线性增加。MBC、MBN、DOC、DON、DOC+MBC和DON+MBN之间呈极显著正相关(P<0.01)。从相关程度看,DOC+MBC和DON+MBN较MBC、DOC、MBN、DON更能反映土壤中活性有机碳和氮库的变化,成为评价土壤肥力及质量的更有效指标。结果可为提高洱海流域农田土壤肥力,增强土壤固氮效果,减少土壤中氮素流失,保护洱海水质安全提供科学依据。