Experimental study on mitigating wind erosion of calcareous desert sand using spray method for microbially induced calcium carbonate precipitation

Wind erosion is one of the significant natural calamities worldwide, which degrades around one-third of global land. The eroded and suspended soil particles in the environment may cause health hazards, i.e.allergies and respiratory diseases, due to the presence of harmful contaminants, bacteria, and pollens.The present study evaluates the feasibility of microbially induced calcium carbonate precipitation(MICP)technique to mitigate wind-induced erosion of calcareous desert sand(Thar desert of Rajasthan province in India). The temperature during biotreatment was kept at 36℃ to stimulate the average temperature of the Thar desert. The spray method was used for bioaugmentation of Sporosarcina(S.) pasteurii and further treatment using chemical solutions. The chemical solution of 0.25 pore volume was sprayed continuously up to 5 d, 10 d, 15 d, and 20 d, using two different concentration ratios of urea and calcium chloride dihydrate viz 2:1 and 1:1. The biotreated samples were subjected to erosion testing(in the wind tunnel) at different wind speeds of 10 m/s, 20 m/s, and 30 m/s. The unconfined compressive strength of the biocemented crust was measured using a pocket penetrometer. The variation in calcite precipitation and microstructure(including the presence of crystalline minerals) of untreated as well as biotreated sand samples were determined through calcimeter, scanning electron microscope(SEM), and energydispersive X-ray spectroscope(EDX). The results demonstrated that the erosion of untreated sand increases with an increase in wind speeds. When compared to untreated sand, a lower erosion was observed in all biocemented sand samples, irrespective of treatment condition and wind speed. It was observed that the sample treated with 1:1 cementation solution for up to 5 d, was found to effectively resist erosion at a wind speed of 10 m/s. Moreover, a significant erosion resistance was ascertained in15 d and 20 d treated samples at higher wind speeds. The calcite content percentage, thickness of crust,bulk density, and surface strength of biocemented sand were enhanced with the increase in treatment duration. The 1:1 concentration ratio of cementation solution was found effective in improving crust thickness and surface strength as compared to 2:1 concentration ratio of cementation solution. The calcite crystals formation was observed in SEM analysis and calcium peaks were observed in EDX analysis for biotreated sand.

MICP技术在地下水封油库渗控注浆中的应用潜力

地下水封油库在建设及运营过程中洞室涌水量大小是影响洞库水封安全和运营成本的重要因素。目前地下水封油库工程建设中采用传统的注浆方式难以将围岩渗透性降低到设计要求,因此洞室涌水量得不到很好的控制。微生物诱导碳酸钙沉淀(MICP)技术具有注浆黏度低、环境适应性强、生成矿化物质稳定等显著优点,引起了学术界与工程界广泛的兴趣和研究。本文首先分析了地下水封油库涌水量控制中存在的相关问题,然后阐述了MICP技术对裂隙渗流控制的机理、影响因素以及对裂隙渗透性的影响效果,最后探讨了MICP技术在地下水封油库中应用的关键问题。通过分析表明,MICP作为地下水封油库渗流控制的一种辅助注浆方式,可以较为准确地控制围岩渗透性变化,达到对洞室涌水量有效控制的目的。

天然海水环境下离子浓度对MICP反应的影响

微生物岩土技术通过生物矿化过程改善基础材料的力学性质,使其更适用于建筑或解决多学科领域的环境问题。微生物矿化过程中产生的碳酸钙是改善基础材料力学性质的主要成分,但其生成量及形态等受多种因素的影响。通过离子计、pH计、SEM、EDS和XRD等手段探究天然海水和去离子水环境在矿化过程中氯化钙和尿素浓度、比例及菌液和胶结液(氯化钙、尿素)体积比等因素对沉淀物质形貌及晶体组成的影响。结果表明:钙离子和尿素浓度及比例低时,碳酸钙的产率较高,但当初始钙离子、尿素浓度超过1.0 mol/L时,离子浓度增大对细菌产脲酶有抑制作用,浓度越高对脲酶的抑制作用越明显,沉淀物产率也随之减小,海水环境总体沉淀量与沉淀效率均高于去离子水环境。菌胶结液体积比去离子水中为1∶4、海水中不高于1∶10时,碳酸钙生成量较高,去离子水环境晶型以方解石为主,海水环境晶型以球霰石为主且沉淀中含有镁盐。

采用MICP加固不同掺砂比例粉土的试验研究

针对微生物诱导碳酸钙沉积(MICP)处理对象多为单一级配土体的现状,开展颗粒级配对MICP加固效果影响的试验研究.通过在粉土中掺入不同比例的标准砂来配置5种不同级配的土样.选用巴氏芽孢杆菌作为微生物,尿素和氯化钙作为胶结液来进行MICP处理.由于制样的密实程度会影响加固效果,将每种级配试样的干密度控制为5个水平.通过试验研究掺砂比例、密实水平等对加固效果的影响.结果表明:试样经过MICP处理得到了整体加固,在粉土中掺入一定比例砂土有助于提高水稳定性.掺砂比例和密实水平对CaCO_(3)生成量和无侧限抗压强度都有影响.在粉土中掺入适量的砂土颗粒有利于提高加固强度;但当砂土掺量过高时,对加固效果有不利影响.增加制样干密度在一定程度上有助于获得更高的强度,但加固强度并不完全取决于初始干密度或孔隙比.

Unconfined compressive strength of MICP and EICP treated sands subjected to cycles of wetting-drying,freezing-thawing and elevated temperature:Experimental and EPR modelling

Microbial-induced carbonate precipitation(MICP)and enzyme-induced carbonate precipitation(EICP)are two bio-cementation techniques,which are relatively new methods of ground improvement.While both techniques share some similarities,they can exhibit different overall behaviours due to the differences in urease enzyme sources and treatment methods.This paper presented 40 unconfined compressive strength(UCS)tests of MICP and EICP treated sand specimens with similar average calcium carbonate(CaCO3)content subjected to cycles of wetting-drying(WD),freezing-thawing(FT)and elevated temperature(fire resistance test e FR and thermogravimetric analysis e TG).The average CaCO3 content after a certain number of WD or FT cycles(ACn)and their corresponding UCS(qn)reduced while the mass loss increased.The EICP treated sand specimens appeared to exhibit a lower resistance to WD and FT cycles than MICP treated specimens possibly due to the presence of unbonded or loosely bonded CaCO3 within the soil matrix,which was subsequently removed during the wetting(during WD)or thawing(during FT)process.FR test and TG analysis showed a significant loss of mass and reduction in CaCO3 content with increased temperatures,possibly due to the thermal decomposition of CaCO3.A complete deterioration of the MICP and EICP treated sand specimens was observed for temperatures above 600C.The observed behaviours are complex and theoretical understanding is far behind to develop a constitutive model to predict qn.Therefore,a multi-objective evolutionary genetic algorithm(GA)that deals with pseudo-polynomial structures,known as evolutionary polynomial regression(EPR),was used to seek three choices from millions of polynomial models.The best EPR model produced an excellent prediction of qn with a minimum sum of squares error(SSE)of 2.392,mean squared error(MSE)of 0.075,root mean square error(RMSE)of 0.273 and a maximum coefficient of determination of 0.939.

椰壳纤维-MICP复合改良膨胀土强度特性

采用椰壳纤维联合微生物诱导碳酸钙沉积(MICP)技术对南水北调中线工程南阳段的膨胀土进行试验改良,开展无侧限抗压强度试验,对比分析素土、纤维土、MICP土以及复合改良土的应力应变特征曲线和破坏形态,并利用响应面法试验研究了椰壳纤维掺量、处理液掺量和胶结液浓度对改良膨胀土无侧限抗压强度的影响,得其最优配比。结果表明:单掺纤维和MICP技术改良均可提升膨胀土的无侧限抗压强度,而复合改良土强度提升最明显,纤维最佳掺量为0.5%;在轴向压力作用下,素土破坏形态表现为“脆性破坏”,MICP土表现为“完全脆性破坏”,纤维土表现为“塑性破坏”,复合改良土表现为“弹塑性破坏”;经统计软件方差分析,对复合改良土强度影响最主要因素是胶结液浓度,其次为处理液掺量、纤维掺量。

MICP加固钙质砂的耐久性试验研究

南海岛礁建设中,钙质砂是易于获取的原材料,但也存在孔隙多、易破碎等不足。为保证岛礁建设的安全稳定,设计经微生物诱导碳酸钙沉积(MICP)加固后钙质砂试样在海水、纯水环境下分别进行浸泡与干湿循环试验,以探究不同环境与处理方式对MICP加固钙质砂样耐久性能的影响。结果表明:(1)经MICP加固的钙质砂具有较好的抗侵蚀能力,通过增加钙质砂的加固轮次能够有效地提高试样的耐久性能,其在海水中干湿循环时劣化最快,在纯水中浸泡时劣化最慢;(2)持续浸泡与干湿循环均会对试样耐久性造成不利影响,干湿循环的劣化作用更大;(3)控制其余变量不变时,海水环境下试样耐久性能的劣化比纯水环境下更严重。

钙源对微生物矿化胶结砂土材料均匀性的影响

微生物诱导碳酸钙沉积(MICP)技术可以改善砂土材料的力学性质,但MICP胶结砂土材料的均匀性问题是目前存在的重要问题,且严重影响了MICP技术的工程应用。进行小尺寸(直径3 cm、高度11 cm)和细长(直径5 cm、高度100 cm)砂柱试样的MICP一批次灌浆试验和溶液环境试验,探究氯化钙和乙酸钙两种钙源对MICP矿化反应过程和MICP胶结砂土材料均匀性的影响。MICP胶结砂土试样的碳酸钙含量和单轴抗压强度试验结果表明,与氯化钙作为钙源相比,乙酸钙作为钙源可以增加砂柱胶结长度,改善碳酸钙在灌浆方向的均匀性,减少MICP胶结砂土材料沿灌浆路径的强度差异;乙酸钙作为钙源可减缓MICP矿化反应过程,降低营养液中尿素的分解速率,进而提高营养液中未分解尿素和游离钙离子在MICP胶结砂土材料中的传输距离,有利于提高MICP胶结砂土材料的均匀性。

MICP矿化产物中钙离子利用率的影响因素及微观物相分析

钙离子利用率是微生物诱导碳酸钙沉积矿化技术中一项重要指标和参数,待矿化钙离子能否参与到矿化反应和如何被利用是这项技术的关键。本文借助紫外线吸光度法、电导率法和EDTA滴定法等技术手段,分析了待胶结菌液浓度和脲酶活性的时变规律,阐述了不同胶结配比对矿化反应过程中钙离子利用率的影响。结果表明:在胶结过程中,细菌的浓度和脲酶活性会逐渐降低;在合理浓度范围内,钙离子利用率随菌液浓度以及胶结液浓度的增大而提高,最高可达99.73%。进而通过X射线衍射、扫描电镜检测来揭示矿化产物的形成机理,分析得出:球霰状碳酸钙晶体是钙离子在有机质的调控下依托细菌表面的成核位点富集矿化而成,矿化产物中碳酸钙晶体尺寸大小和形态受菌液和胶结液配比浓度的影响。本研究对于微生物诱导矿化反应生成碳酸钙在工程材料领域的应用具有一定的参考价值。

MICP在建筑材料中的应用研究

利用微生物在新陈代谢过程中发生的矿化作用,进行诱导形成碳酸钙,称之为微生物诱导碳酸钙沉积(MICP),其生成的碳酸钙沉淀是一种有机-无机合成物,具有优异的粘结性和固结性能。在总结国内外相关资料的基础上,介绍了MICP的形成条件与反应过程,分析了MICP技术在石灰石、石膏、水泥混凝土等建筑材料中的研究和应用情况,并指出MICP在水泥混凝土中应用需选择适当的微生物种类,调整微生物的培育环境和生长空间,并研究新型微生物生长保护措施。

微生物岩土工程技术的过去、现在与未来

微生物岩土工程技术作为一种新兴的生态友好型岩土体改良加固技术,应用前景广阔。但限于理论水平和研究手段,该技术仍存在较多不足,难以实现高效固化,由此成为大规模现场应用的瓶颈。而提升固化效率的关键在于明确其作用原理和影响机制。文章梳理了微生物诱导碳酸钙沉积技术(MICP)的研究现状,系统归纳了固化原理和改良岩土体的物理力学特性,并分析得出固化效率主要受到反应物自身和外部环境两方面的影响。当前MICP技术已初步应用于土体固化、裂缝修复、防渗处理、污染修复及微生物水泥等领域,但由于矿化难以均匀、反应物不经济、微生物及脲酶活性期短且受环境干扰大、代谢产物附带毒性、现场应用性差,该技术目前主要限于实验室水平。作者分别提出了可能的突破与改进方向,并结合实验室成果指出豆粕进行菌体扩培和脲酶供给的碳源优势,以及将磷石膏作为现场钙源的环保性和经济性,以期为从事微生物岩土工程研究与技术开发的人员提供参考。

砂土基MICP土工材料剪切强度试验及可靠性分析

选用巴氏芽孢杆菌,以不同粒径砂土为岩土基质,应用微生物诱导矿化技术生成MICP-土工材料试样,自然养护7d后,应用直剪仪进行了抗剪强度测试试验。结果表明,MICP-细砂土内摩擦角范围最大,MICP-粗粒砂土内摩擦角范围最小,这与微生物诱导生成的矿化物填充空隙的过程中形成胶结作用有重要的关系,粗粒砂土空隙大,MICP材料强度的增长主要依靠诱导生成的碳酸钙咬合力;中粗砂粒土表面粗糙度的提高有效增强了矿化土工材料的强度;细砂土主要是填充空隙,材料更加密实,导致抗剪强度最大。再运用多项式混沌扩展(PCE)方法建立代理模型,求得其前四阶统计矩,对内摩擦角输出响应的不确定性进行了量化。

Biomineralization and mineralization using microfluidics:A comparison study

Biomineralization through microbial process has attracted great attention in the field of geotechnical engineering due to its ability to bind granular materials,clog pores,and seal fractures.Although minerals formed by biomineralization are generally the same as that by mineralization,their mechanical behaviors show a significant discrepancy.This study aims to figure out the differences between biomineralization and mineralization processes by visualizing and tracking the formation of minerals using microfluidics.Both biomineralization and mineralization processes occurred in the Y-shaped sandcontaining microchip that mimics the underground sand layers.Images from different areas in the reaction microchannel of microchips were captured to directly compare the distribution of minerals.Crystal size and numbers from different reaction times were measured to quantify the differences between biomineralization and mineralization processes in terms of crystal kinetics.Results showed that the crystals were precipitated in a faster and more uncontrollable manner in the mineralization process than that in the biomineralization process,given that those two processes presented similar precipitation stages.In addition,a more heterogeneous distribution of crystals was observed during the biomineralization process.The precipitation behaviors were further explained by the classical nucleation crystal growth theory.The present microfluidic tests could advance the understanding of biomineralization and provide new insight into the optimization of biocementation technology.

Application of Bioengineering in Construction

Bio-cement and bio-concrete are innovative solutions for sustainable construction, aiming to reduce environmental impact while maintaining the durability and versatility of building materials. Bio-cement is an eco-friendly alternative to traditional cement, produced through Microbially Induced Calcium Carbonate Precipitation (MICP), which mimics natural biomineralization processes. This method reduces CO2 emissions and enhances the strength and durability of construction materials. Bio-concrete incorporates bio-cement into concrete, creating a self-healing material. When cracks form in bio-concrete, dormant bacteria within the material become active in the presence of water, producing limestone to fill the cracks, extending the material’s lifespan and reducing the need for repairs. The environmental impact of traditional cement production is significant, with cement generation accounting for up to 8% of global carbon emissions. Creative solutions are needed to develop more sustainable construction materials, with some efforts using modern innovations to make concrete ultra-durable and others turning to science to create affordable bio-cement. The research demonstrates the potential of bio-cement to revolutionize sustainable building practices by offering a low-energy, low-emission alternative to traditional cement while also addressing environmental concerns. The findings suggest promising applications in various construction scenarios, including earthquake-prone areas, by enhancing material durability and longevity through self-repair mechanisms.

微生物矿化加固砂土的试验研究

近年来微生物诱导碳酸钙沉积(MICP)技术作为一种新型的绿色加固方法,得到了广泛研究,但传统的MICP固化方式注浆管法存在管口易堵塞且固化试样强度分布不均匀的问题,为改善MICP固化土体的强度分布不均匀性问题,利用巴士芽孢杆菌BNCC337394开展了使用新型柔性土工模具加固砂土的试验研究。通过对固化试样的CaCO_(3)含量分布,无侧限抗压强度,试样的均匀性等方面进行分析,综合评价利用新型土工模具加固砂土的效果。结果表明:利用新型柔性土工模具固化砂土具有较好效果,经固化后的试样无侧限抗压强度可达3.07MPa,且固化试样均匀性良好。

MICP联合纤维加筋改性钙质砂的动力特性研究

为了提高我国南海钙质砂地基的抗液化性能,提出利用微生物诱导碳酸钙沉积(MICP)技术联合纤维加筋技术对钙质砂进行改性处理。通过开展动三轴试验,对比分析了改性前后钙质砂试样的动应变、动孔压、应力-应变滞回曲线以及动弹性模量的发展规律和演化特征,并结合扫描电镜(SEM)试验探究了MICP和纤维加筋技术对钙质砂的联合改性机制。研究结果表明:(1)MICP技术可以明显改善钙质砂试样的抗变形与抗液化性能,相比于未胶结处理试样,仅MICP处理试样的动应变和动孔压分别降低了95.74%和92.46%;(2)纤维的掺入进一步提升了MICP的改性效果,相比于仅MICP处理试样,MICP和纤维加筋联合处理试样的动应变和动孔压分别降低了74.32%和74.18%;(3)MICP和纤维加筋技术通过减轻试样在循环荷载作用下的循环活动强度和能量耗散、提高试样的动弹性模量和减小动弹性模量的衰减速率,从而实现试样抗变形与抗液化性能的显著提高;(4)SEM试验分析结果表明,MICP与纤维对钙质砂动力特性的改善具有协同作用。纤维的掺入为细菌提供了更多的附着场所,促进了碳酸钙晶体的生成量,该部分碳酸钙不仅增加了颗粒间的胶结强度,同时也将纤维固定在砂颗粒上增强了纤维网的约束作用。

海水环境下MICP胶结钙质砂干湿循环试验研究

为了探究微生物诱导碳酸钙沉积(MICP)在海水环境中胶结钙质砂的适用性与MICP胶结体的耐干湿循环性能,分别在海水与淡水环境中试验MICP胶结钙质砂,并在海水环境中对MICP胶结的钙质砂进行干湿循环.基于能谱分析(EDS)与X射线衍射(XRD)分析胶结体元素与矿物组成.通过无侧限抗压强度试验、称重,构建胶结体的力学性质、质量损失与干湿循环的关系,利用扫描电子显微镜(SEM)分析干湿循环弱化机制.结果表明:海水环境中MICP对钙质砂的胶结效果优于淡水环境;海水环境中MICP胶结的钙质砂体具有比淡水环境中胶结的钙质砂更高的耐干湿循环性能,21次干湿循环后,海水、淡水环境胶结试样的无侧限抗压强度分别下降至原样的30%和7.53%;干湿循环减弱了颗粒表面粗糙度与粒间胶结强度,宏观上表现为MICP胶结的钙质砂体的强度、刚度的降低.

MICP技术用于水泥基材料的改性试验方法对比

针对微生物诱导碳酸钙沉淀(microbial induced calcium carbonate precipitation,MICP)技术用于水泥基材料的改性试验工艺进行研究,探究了拌合、浸泡、真空抽压、二阶段工艺下MICP对水泥基材料的抗压强度影响,并使用扫描电子显微镜(scanning electron microscope,SEM)进行分析。通过对比不同试验方法改性效果得出基于达西定律渗透原理用于材料改性试验的二阶段工艺方法。结果表明,随着二阶段处理次数的不断增加,其强度变化与其他3种差距越来越大,经过6次循环处理后的试样强度较标准养护提高24%,比真空抽压处理强度提高20%,比浸泡处理强度提高22%,比拌合处理强度提高46%。

纤维加筋MICP固化钙质砂的抗拉强度特性研究

针对微生物诱导碳酸钙沉积(MICP)固化钙质砂脆性强、抗拉强度低等问题,通过制备“8”字形MICP固化钙质砂试样并开展直接拉伸试验,对纤维加筋的改善作用、纤维-MICP联合加固机理及纤维掺量、纤维长度等影响因素进行了研究。结果表明:纤维加筋能够显著提高抗拉强度、峰值位移和残余强度,减轻峰值强度点的脆性破坏现象,但受纤掺量和长度的影响,总的来说,抗拉强度随纤维掺量的增加和长度的加长呈先增后减的趋势。相比无纤维试样,添加最优纤维掺量(0.6%)时,试样的抗拉强度增长了172.4%,峰值变形提升了158.1%。机理可解释为纤维增加了微生物的吸附量,促进碳酸钙在纤维与钙质砂之间以及纤维表面的沉积,增大纤维与钙质砂之间的界面作用力,整体提升钙质砂的抗拉强度特性。纤维的添加能够显著改变试样的变形特征,无纤维添加试样曲线仅有初始误差阶段和弹性阶段两个阶段,添加纤维后曲线表现为四个阶段包括初始误差阶段、弹性阶段、损伤破坏阶段和残余阶段。纤维掺量影响的内因是纤维与钙质砂的界面作用力和纤维空间分布状态随纤维掺量的变化而变化,纤维长度的影响主要和破坏面附近纤维数量和单位长度所能承担的拉应力相关。研究成果对以钙质砂为地基的岛礁工程的稳定性、安全性具有一定的指导意义。

海水环境下MICP的反应机理与影响因素

为了探讨海水环境下微生物矿化反应过程与影响因素,在海水和去离子水环境下,通过改变营养盐浓度、菌液与营养盐体积比、环境温度等条件进行微生物诱导碳酸钙沉淀(Microbially Induced Carbonate Precipitation,MICP)水溶液试验,然后通过SEM、XRD和EDS测试对水溶液生成物进行检测,并推测海水环境下MICP的反应机理。结果表明:不同水环境条件下,营养盐浓度为1 mol/L、菌液与营养盐体积比为30∶120时,反应速率最快,且生成沉淀物质量最大;温度对于碳酸钙沉淀反应影响明显,与低温(4℃)条件相比,室温(25℃)下反应速率更大,且反应进行得较充分;海水环境水溶液试验中,高pH值可以加速反应的进行,同时,由于海水中存在Mg^(2+)、Ba^(2+)等离子,使得沉淀物中除CaCO_(3)外,还含有少量的碱式碳酸镁(Mg_(5)(CO_(3))_(4)(OH)_(2)·4H_(2)O)、BaCO_(3)等矿物成分。