Effect of CO_(2)exposure on the mechanical strength of geopolymerstabilized sandy soils

In recent years,there has been growing interest in developing methods for mitigating greenhouse effect,as greenhouse gas emissions continue to contribute to global temperature rise.On the other hand,investigating geopolymers as environmentally friendly binders to mitigate the greenhouse effect using soil stabilization has been widely conducted.However,the effect of CO_(2)exposure on the mechanical properties of geopolymer-stabilized soils is rarely reported.In this context,the effect of CO_(2)exposure on the mechanical and microstructural features of sandy soil stabilized with volcanic ash-based geopolymer was investigated.Several factors were concerned,for example the binder content,relative density,CO_(2)pressure,curing condition,curing time,and carbonate content.The results showed that the compressive strength of the stabilized sandy soil specimens with 20%volcanic ash increased from 3 MPa to 11 MPa.It was also observed that 100 kPa CO_(2)pressure was the optimal pressure for strength development among the other pressures.The mechanical strength showed a direct relationship with binder content and carbonate content.Additionally,in the ambient curing(AC)condition,the mechanical strength and carbonate content increased with the curing time.However,the required water for carbonation evaporated after 7 d of oven curing(OC)condition and as a result,the 14-d cured samples showed lower mechanical strength and carbonate content in comparison with 7-d cured samples.Moreover,the rate of strength development was higher in OC cured samples than AC cured samples until 7 d due to higher geopolymerization and carbonation rate.

Laboratory-scale model of carbon dioxide deposition for soilstabilisation

Olivine sand is a natural mineral,which,when added to soil,can improve the soil’s mechanical properties while also sequester carbon dioxide(CO2)from the surrounding environment.The originality of this paper stems from the novel two-stage approach.In the first stage,natural carbonation of olivine and carbonation of olivine treated soil under different CO2pressures and times were investigated.In this stage,the unconfined compression test was used as a tool to evaluate the strength performance.In the second stage,details of the installation and performance of carbonated olivine columns using a laboratory-scale model were investigated.In this respect,olivine was mixed with the natural soil using the auger and the columns were then carbonated with gaseous CO2.The unconfined compressive strengths of soil in the first stage increased by up to 120% compared to those of the natural untreated soil.The strength development was found to be proportional to the CO2pressure and carbonation period.Microstructural analyses indicated the presence of magnesite on the surface of carbonated olivinetreated soil,demonstrating that modified physical properties provided a stronger and stiffer matrix.The performance of the carbonated olivine-soil columns,in terms of ultimate bearing capacity,showed that the carbonation procedure occurred rapidly and yielded a bearing capacity value of 120 k Pa.Results of this study are of significance to the construction industry as the feasibility of carbonated olivine for strengthening and stabilizing soil is validated.Its applicability lies in a range of different geotechnical applications whilst also mitigates the global warming through the sequestration of CO2.

Soil CO_2 evolution from Korean pine virgin forest at Changbai Mountain

The soil CO2 evolution rate was measured in a virpin Korean pine forest. The results in June showed that the lowest value of evolution rate was 220 mg /(m2·h) and appeared at 6:00 a.m. The highest value was 460 mg /(m2·h) at 18:00. The rates of CO2 evolution were related with soil temperature. On the basis of the constructed regression equation and the monthly average values of temperature, the magnitude of CO2 evolution from Korean pine forest soil was 10.4 t /hm2 during a growing season.

杉木人工林林地土壤CO_2释放量及其影响因子的研究

采用碱液吸收法对湖南省会同生态定位站郁闭杉木人工林林地土壤CO2 释放量进行测定 ,并分析温度、水分和土壤C N比对林地土壤CO2 释放量的影响。结果表明 :郁闭杉木人工林林地土壤CO2 释放量在 0 10 5 2～0 5 5 90g·m- 2 h- 1 之间变化 ,且具有一定的季节变化规律 ,总体趋势是夏季高 ,其他季节低 ;林地土壤CO2 释放量与林内气温、土壤各层 (0、5、10、15、2 0cm)温度和土壤各层 (0、10、2 0cm)含水量在一定范围内呈一元线性正相关 ,与土壤C N比也呈一元线性正相关 ;以林内气温、土壤各层 (0、5、10、15、2 0cm)温度为依据得到的Q1 0 依次为 2 0 8、2 2 2、1 94、2 2 8、2 5 1、2 2 3;林地土壤CO2 释放量与林内气温的相关性最强 ,为极显著相关 ,偏相关系数为 0 916 (p <0 0 1) ,与土壤各层 (0、5、10、15、2 0cm)温度也是极显著相关 ,偏相关系数均在 0 818以上 (p <0 0 1) ,但与土壤C N比和土壤各层 (0、10、2 0cm)含水量相关不显著 ,偏相关系数为 0 4 5 2～ 0 6 12 (p >0 0 5 )

尖峰岭热带森林土壤C储量和CO_2排放量的初步研究

本文根据定位观测数据和有关历史资料，研究了海南岛尖峰岭林区主要森林土壤的有机Ｃ储量、热带山地雨林和半落叶季雨林凋落物的Ｃ储量和林地ＣＯ２的排放量、以及“刀耕火种”和砍伐森林等人类活动对土壤Ｃ的影响，对于进一步认识热带林的生态功能，弄清我国温室气体的排放量，正确评价中国森林在全球生物圈Ｃ平衡中的作用，具有一定的参考价值。

郯庐断裂带南段双山韧-脆性剪切带物质迁移与CO_2释放研究

根据动力变质作用的特点,在野外和室内正确鉴别区分郯庐断裂安徽肥东双山一带不同变质等级的动力变质带的矿物组合特点,应用体积亏损-元素得失方程,计算了在应力作用条件下,不同变质带内,不同等级的碳酸盐岩地层的各元素(组分)的得失状况,特别仔细深入地模拟计算了不同岩性的动力变质岩在构造应力作用下的CO_2的释放量和释放机制,从而为探讨和研究动力变质作用下,碳酸盐岩地区岩石生成CO_2的过程提供理论和实践上的依据。

西安东南部7月份土壤CO_2释放量和释放规律研究

根据碱溶液吸收法 ,对西安东南部地区 7月份不同植被条件下土壤CO2 释放量进行了昼夜观测 .观测资料显示 ,西安东南部地区 7月份土壤CO2 释放量在一昼夜内具有明显变化 ,从当日 9时到次日 9时 ,CO2 释放量表现出由低变高再变低的规律 .土壤CO2 释放量变化与温度变化具有相同的特征 ,但释放量的变化具有滞后性 ,相对于温度的变化滞后 4～ 6h .温度是决定土壤CO2 释放量昼夜变化规律的主要因素 ,它的升高和降低分别造成了土壤CO2 释放量的增加和减少 .不同植被条件下 ,土壤CO2 释放量不同 ,林地释放量大于草地 ,草地释放量大于裸地 ,夜间 1 2h释放量大于白天 1 2h释放量 .

陆地生态系统土壤CO_(2)排放对模拟增温的响应特征及影响因素

全球变暖已经成为不争的事实,陆地生态系统碳循环的研究受到了各界广泛关注,是当前全球变化研究中的重点。土壤CO_(2)排放是陆地生态系统与大气间二氧化碳交换的最大通量之一,当前陆地生态系统中土壤CO_(2)排放如何响应全球气候变暖及其影响因素仍不清楚,限制了对土壤碳循环过程及影响机制的深入认识。旨在明确全球变暖背景下陆地生态系统中土壤CO_(2)排放格局及影响因素。基于Web of Science、PubMed和中国知网等中英文期刊数据库,充分收集全球范围内的相关野外试验文献81篇,提取出65个研究位置和213组相关研究数据,采用Meta分析方法探讨陆地生态系统土壤CO_(2)排放对增温的响应特征,分析其与海拔、气候、土壤含水量、容重(BD)、pH、全氮(TN)和土壤有机碳(SOC)的相关关系。结果表明:陆地生态系统中土壤CO_(2)排放对增温整体有显著的正向响应,在农、林、草生态系统中,增温使土壤CO_(2)排放分别显著增加13.1%、18.0%、5.9%(P<0.05),森林生态系统对增温响应的正效应最强烈;增温能在短时期内促进土壤呼吸,但随着增温持续时间增加,土壤呼吸对温度的敏感性会降低,对温度变化产生适应性,从而使其对增温的响应能力减弱;响应特征受到环境因子、土壤特性以及其他试验条件等的影响,绝大多数条件下对增温表现出显著的正响应特征,不同影响因子之间共同作用、相互影响。增温通常能够改变植物生物量、土壤养分含量及微生物数量和活性,从而影响到植被根际呼吸和土壤呼吸速率。相关分析表明,海拔对土壤CO_(2)排放有显著负向影响,而年均气温、年均降水量、土壤含水量和仪器嵌入土壤深度则对土壤CO_(2)排放产生显著正向影响。这些结果对于理解全球土壤CO_(2)排放的时空变化格局有重要意义,也为准确评价全球变暖背景下土壤碳汇功能及其持续性提供理论依据。

大气CO_(2)浓度对萝卜生长及氮磷钾养分吸收的影响

【目的】探明CO_(2)浓度升高是否改变土壤养分状况进而影响萝卜生长及养分吸收,为大气CO_(2)浓度升高条件下萝卜合理施肥方式提供理论依据。【方法】以糖晶萝卜为试验材料,设置4个CO_(2)浓度水平:C_(0)(大气CO_(2)浓度)、C_(1)(C_(0)+33%C_(0))、C_(2)(C_(0)+67%C_(0))和C_(3)(C_(0)+100%C_(0)),研究不同CO_(2)浓度对萝卜生长、氮磷钾养分吸收及土壤养分的影响。【结果】与C_(0)相比,C_(1)、C_(2)和C_(3)处理萝卜地上生物量增加0.52%~34.68%,地下生物量增加63.00%~100.46%,总生物量增加37.83%~67.61%,CO_(2)浓度升高促进萝卜生长和干物质积累,且C_(2)处理最适宜;CO_(2)浓度升高降低萝卜地下氮磷和地上钾含量,但植株氮磷钾积累量分别增加39.77%~43.30%、2.08%~17.27%和38.38%~72.26%。土壤硝态氮、有效磷和速效钾在CO_(2)浓度升高条件下分别降低29.62%~34.20%、10.03%~14.12%和1.92%~16.62%。植株氮和钾积累量与植株干重呈显著正相关,与土壤硝态氮、有效磷和速效钾呈显著负相关。【结论】CO_(2)浓度升高通过增加脲酶和磷酸酶活性改善土壤肥力,促进植株氮磷钾养分吸收,进而提高萝卜产量。在大气CO_(2)浓度升高条件下,应合理增施氮肥、磷肥、钾肥,且氮肥施用量应大于磷肥和钾肥。

连续翻压黑麦草对豫中植烟土壤剖面CO_(2)日排放变化的影响

【目的】探究豫中烟区翻压黑麦草对烤烟生长过程中土壤呼吸速率、土壤剖面二氧化碳(CO_(2))日排放变化的影响及其与环境因子的关系,明确CO_(2)采集最佳观测时间。【方法】2021年在河南农业大学郑州科教园区设置2个处理(依托于长期定位试验),施氮磷钾肥(NPK)、氮磷钾+种植并翻压黑麦草(NPKG),烟苗移栽后每隔30d测定烟田CO_(2)排放日变化过程。【结果】(1)0~10 cm地温与土壤呼吸速率均表现为昼高夜低的单峰或双峰形态。NPKG处理土壤呼吸速率显著高于NPK处理,9:00和21:00矫正系数最接近1且与日平均排放无显著差异。(2)随着土层加深,CO_(2)浓度升高,CO_(2)扩散通量降低,同层土壤NPKG处理CO_(2)浓度和扩散通量高于NPK处理。0、5、10和20 cm土层CO_(2)浓度和0~20 cm土层扩散通量有明显日变化特征,90 d时CO_(2)浓度较60 d降低。(3)土壤呼吸速率与0~20 cm土层CO_(2)扩散通量呈显著或极显著正相关关系。【结论】黑麦草翻压加快土壤呼吸速率、提高了各土层CO_(2)浓度和CO_(2)扩散通量。9:00左右和21:00左右为最佳取样时间段,5 cm和10 cm土层CO_(2)浓度和5~10 cm土层扩散通量与土壤呼吸速率日变化特征相似,3个取样日CO_(2)浓度以60 d最高,30 d次之。可根据土壤CO_(2)浓度预测土壤呼吸速率。

樟树人工林林地CO_2释放量的研究

对湖南省株洲市樟树人工林不同坡向 (南、北坡 )林地 CO2 释放量进行定位观测 .结果表明 :樟树人工林林地 CO2 释放量一般是在 0 .0 40 6～ 0 .42 2 9g·m- 2 h- 1之间 ,平均值为 0 .2 669g·m- 2 h- 1 ,且呈一定的季节变化 ;坡向对林地 CO2 释放量的影响不明显 ;林地 CO2 释放量与各层土壤温度、含水量在一定范围内呈线性相关性 ;林地 CO2 释放量昼夜变化有一定规律性 .根据观测的林地 CO2 释放量日平均值计算得出 ,樟树人工林林地释放 CO2 通量估计范围为 13. 5 6～ 94.42 kg· hm- 2 d- 1 ,平均为61.78kg· hm- 2 d-

两种气体作用下非饱和江边吹填砂三轴试验研究

为了研究非饱合土体中充入空气或CO_(2)气体所导致的土样不同物理力学性质,以长江边的吹填细砂为对象,通过改变细砂的含水率,往土样通入空气和CO_(2),采用固结不排水三轴试验分析了两种不同气体作用下细砂的应力-应变曲线及抗剪强度指标。研究结果表明:两种气体在低围压下使得细砂的应力-应变曲线表现为应变软化型,高围压下曲线为硬化型。围压作用下充CO_(2)细砂具有低孔隙率和高密实度特征,导致充CO_(2)细砂的抗剪强度大于充空气的细砂。在高围压下,细砂颗粒联系更加紧密,更多依靠颗粒骨架传递应力,使得两种气体作用下细砂抗剪强度的差别变小。细砂含水率从4%增至12%时,充CO_(2)细砂的黏聚力是充空气细砂黏聚力的2.62~4.37倍,据此可在工程建设中对有机质含量高的非饱合细砂充入CO_(2)气体,以起到加固土体的效果。

亚热带喀斯特森林土壤CO_2排放量动态研究

该文用吸收阱法研究了亚热带喀斯特森林土壤CO2 排放量在不同季节的昼夜变化规律。得出茂兰喀斯特森林土壤中CO2 排放量与气候变化有关 ,冬春季森林土壤CO2 排放量较小 ,夏秋季土壤CO2 排放量大。春季CO2 的排放量日均为6 5 5 2 77mg .m-2 .h-1,夏季为 2 81 7385mg .m-2 .h-1,秋季为 339 6 792mg .m-2 .h-1,冬季为 2 0 6 5 86 8mg .m-2 .h-1。年均排放量为 1 95 6 8kg .m-2 .yr-1。排放量的昼夜变化明显 ,春季 14点至 18点排放量最大 ,18点至 2 2点最小 ;秋季则为 19点至 2 3点排放量最大 ,凌晨 3点至 7点最小。春夏季白天排放量大于夜间排放量 。

Dredged marine soil stabilization using magnesia cement augmented with biochar/slag

Dredged marine soils(DMS)have poor engineering properties,which limit their usage in construction projects.This research examines the application of reactive magnesia(rMgO)containing supplementary cementitious materials(SCMs)to stabilize DMS under ambient and carbon dioxide(CO_(2))curing conditions.Several proprietary experimental tests were conducted to investigate the stabilized DMS.Furthermore,the carbonation-induced mineralogical,thermal,and microstructural properties change of the samples were explored.The findings show that the compressive strength of the stabilized DMS fulfilled the 7-d requirement(0.7-2.1 MPa)for pavement and building foundations.Replacing rMgO with SCMs such as biochar or ground granulated blast-furnace slag(GGBS)altered the engineering properties and particle packing of the stabilized soils,thus influencing their performances.Biochar increased the porosity of the samples,facilitating higher CO_(2) uptake and improved ductility,while GGBS decreased porosity and increased the dry density of the samples,resulting in higher strength.The addition of SCMs also enhanced the water retention capacity and modified the pH of the samples.Microstructural analysis revealed that the hydrated magnesium carbonates precipitated in the carbonated samples provided better cementation effects than brucite formed during rMgO hydration.Moreover,incorporating SCMs reduced the overall global warming potential and energy demand of the rMgO-based systems.The biochar mixes demonstrated lower toxicity and energy consumption.Ultimately,the rMgO and biochar blend can serve as an environmentally friendly additive for soft soil stabilization and permanent fixation of significant amounts of CO_(2) in soils through mineral carbonation,potentially reducing environmental pollution while meeting urbanization needs.

Influencing factors and partitioning methods of carbonate contribution to CO_(2)emissions from calcareous soils

In calcareous soils,recent studies have shown that soil-derived CO_(2)originates from both soil organic carbon(SOC)decomposition and soil inorganic carbon(SIC)dissolution,a fact often ignored in earlier studies.This may lead to overestimation of the CO_(2)emissions from SOC decomposition.In calcareous soils,there is a chemical balance between precipitation and dissolution of CaCO_(3)-CO_(2)-HCO_(3),which is affected by soil environmental factors(moisture,temperature,pH and depth),root growth(rhizosphere effect)and agricultural measures(organic materials input,nitrogen fertilization and straw removal).In this paper,we first introduced the contribution of SIC dissolution to CO_(2)emissions from calcareous soils and their driving factors.Second,we reviewed the methods to distinguish two CO_(2)sources released from calcareous soils and quantify the 13C fractionation coefficient between SIC and SIC-derived CO_(2)and between SOC and SOC-derived CO_(2),and to partition three CO_(2)sources released from soils with plants and organic materials input.Finally,we proposed methods for accurately distinguishing three CO_(2)sources released from calcareous soils.This review helps to improve the accuracy of soil C balance assessment in calcareous soils,and also proposes the direction of further investigations on SIC-derived CO_(2)emissions responses to abiotic factors and agricultural measures.

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。

蚯蚓活动对毛竹林土壤二氧化碳排放及活性有机碳的影响

【目的】土壤动物对土壤碳循环至关重要。探究蚯蚓活动对毛竹Phyllostachys edulis林下土壤二氧化碳(CO_(2))排放及活性有机碳变化的影响。【方法】通过3个月的温室盆栽试验,以单独种植毛竹为对照(ck),以分别添加凋落物(MBL)和凋落物及蚯蚓(MBLE)为处理,采用静态箱-气相色谱法分段采集并分析土壤释放的CO_(2),测定土壤有机碳、颗粒态有机碳、可溶性有机碳、矿物结合态有机碳以及微生物生物量碳质量分数。【结果】蚯蚓活动极显著增加了20.3%的毛竹生物量(P<0.01),其对土壤CO_(2)排放的影响随时间变化敏感。试验前期(<51 d),MBLE处理与MBL处理的CO_(2)累积排放量无显著性差异,而试验后期(>51 d),MBLE处理的CO_(2)累积排放量显著高于MBL处理(P<0.05),但试验结束时(第85天),MBLE处理的土壤CO_(2)累积排放量较MBL处理仅增加4.5%。此时,MBL处理土壤CO_(2)排放通量较MBLE处理高25.2%。土壤碳质量分数对蚯蚓活动的响应同样随时间变化敏感。MBLE处理下的土壤有机碳、可溶性有机碳、颗粒态有机碳及矿物结合态有机碳质量分数在前68 d均低于MBL处理,但试验结束时(第85天),MBLE处理的可溶性有机碳质量分数显著提高了15.2%(P<0.05);土壤有机碳、矿物结合态有机碳和颗粒态有机碳质量分数分别提高了8.5%、8.5%和10.6%;但土壤微生物生物量碳质量分数极显著降低了26.3%(P<0.01)。【结论】蚯蚓活动可促进毛竹生长,增加毛竹林土壤碳质量分数,并在试验结束时降低土壤CO_(2)排放通量及累积排放量。

西安地区土壤CO_2释放量和释放规律

根据碱溶液吸收法 ,对西安地区不同植被条件下土壤CO2 释放量进行了昼夜观测 .观测资料显示 ,西安地区各月份土壤CO2 释放量在一昼夜内具有明显的变化 ,从当日上午到次日上午 ,CO2 释放量表现出由低变高再变低的规律 .土壤CO2 释放量变化与温度变化具有相同的特征 ,但释放量的变化具有滞后性 ,相对于温度的变化滞后 4～ 6h左右 .温度是决定土壤CO2 释放量昼夜变化规律的主要因素 ,它的升高和降低分别造成了土壤CO2 释放量的增加和减少 .不同植被条件下 ,土壤CO2 释放量不同 ,林地释放量大于草地 ,草地释放量大于裸地 .夜间1 2h释放量大于白天 1

内蒙古大青山不同植被类型土壤CO_(2)通量及其对土壤温湿度的响应

为研究大青山典型植被土壤CO_(2)通量特征及其影响因素,采用静态箱‒气相色谱法测定内蒙古大青山主要植被类型油松(Pinus tabuliformis)人工林、白桦(Betula platyphylla)次生林、虎榛子(Ostryopsis davidiana)灌木林、荒草坡地土壤CO_(2)的排放规律及与土壤温湿度的关系。结果表明:(1)4种植被类型在观测期内土壤CO_(2)通量范围为11.00~673.47 mg.m^(-2).h^(-1),均为大气CO_(2)的源;(2)各样地土壤CO_(2)通量平均值大小为:荒草坡地<油松人工林<虎榛子灌木林<白桦次生林;(3)土壤温度是影响不同植被类型土壤CO_(2)通量的主要因子,土壤含水量影响不明显;(4)大青山4种植被类型土壤呼吸Q10值范围为1.07~5.64,不同植被类型间Q10值存在较大差异,Q10均值大小为:白桦次生林>荒草坡地>油松人工林>虎榛子灌木林。相关研究结果可为准确估算大青山典型植被土壤CO_(2)通量提供基础数据。

Distribution of CO_(2)in Soil Air Affected by Vegetation in the Shilin National Park

This paper studies the CO2 distribution of soil atmosphere in the Shilin National Park. The measurement sites were chosen according to different topographic features and different vegetations. Seven measurement sites on 3 cross sections were chosen to pass through 3 karstic depressions or on the slopes of depressions. All measurement results show soils with pH values lower than 7.0 (from 5.4 to 6.6). There are 2 cases for the pH values of soil in different topographic features: the pH values of 2 profiles on the ridges or upper slopes of depressions are lower than those in the depressions; and the pH values of 2 soil profiles on the slopes of depressions are higher than those in the depressions. Most samples show relatively low humidity and CO2 contents on the ridges or slopes of depressions compared with soil profiles in the depressions. High CO2 contents occur at depths from ?40 to ?80 cm and high and dense grassland shows high CO2 contents in the soil atmosphere. Grass roots may grow and are distributed mainly at depths from ?20 to ?40 cm; while tree roots predominantly as deep as ?60 cm even ?80 cm. The influences of pine, cypress and eucalyptus on soil CO2 have been studied. Soil CO2 influenced by pine and cypress are generally concentrated in an area surrounding the tree with a diameter of 1 m and the strongly influenced distance is 50 cm. Eucalyptus will strongly affect the CO2 contents in an area with a diameter of 2 m, especially 1 m distant from the tree. The highest concentration of soil CO2 at a depth of ?30 and 100 cm from the tree reaches 92000 ppm.