An experimental study on dynamic response for MICP strengthening liquefiable sands

The technology of bio-gronting is a new technique for soft ground improvement. Many researchers have carried out a large number of experiments and study on this topic. However, few studies have been carried out on the dynamic response of solidified sand samples, such reducing liquefaction in sand. To study this characteristic of microbial-strengthened liquefiable sandy foundation, a microorganism formula and grouting scheme is applied. After grouting, the solidified samples are tested via dynamic triaxial testing to examine the cyclic performance of solidified sand samples. The results indicate that the solidified sand samples with various strengths can be obtained to meet different engineering requirements, the use of bacteria solution and nutritive salt is reduced, and solidified time is shortened to 1-2 days. Most importantly, in the study of the dynamic response, it is found that the MICP grouting scheme is effective in improving liquefiable sand characteristic, such as liquefaction resistance.

MICP固化粉土细菌的分布和固定规律研究

采用一维注浆方式对50 cm长柱状粉土试样进行微生物固化试验,通过测定孔隙液中细菌数量、NH+4浓度和pH、及固化土体中的胶结CaCO_3生成量等参量,分析注浆菌液配比和胶结液浓度对细菌与反应产物沿程分布特性的影响。结果表明,当注入浓度为1.223×108 CFU/mL的原菌液时,固定菌与游离菌沿柱状试样渗流方向沿程衰减显著,细菌主要分布于注浆端25 cm以内,提高胶结液浓度对试样碳酸钙生成量的影响主要集中在注浆端5 cm以内区域。当注入用营养液稀释的菌液(浓度8.20×106 CFU/mL)或用营养液稀释的上清液(浓度1.80×106 CFU/mL)时,孔隙液中细菌能快速繁殖增长且分布较为均匀,吸附菌和被拦截的游离菌共同组成固定菌,对土中碳酸钙的生成量产生影响,胶结液浓度的变化对碳酸钙生成量的影响较小。研究结果表明,微生物注浆加固粉土的均匀性主要受固定菌分布的均匀性控制,将菌液或上清液稀释后注入粉土能够使固定菌沿程分布均匀,可较好地改善固化土体均匀性。

纳米四氧化三铁对微生物诱导碳酸钙沉淀的作用效果与机理研究

微生物诱导碳酸钙沉淀(MICP)是环境岩土工程领域一项新型的土体加固技术。微生物的生长及活性会受到外部磁场的影响,改变MICP中碳酸钙的晶型晶貌及沉淀方式,从而对碳酸钙的胶结性能产生影响。采用纳米四氧化三铁(Nano-Fe_(3)O_(4)),设计了Nano-Fe_(3)O_(4)作用下的微生物诱导碳酸钙沉淀的水溶液及MICP砂土固化试验,对比分析了Nano-Fe_(3)O_(4)含量对微生物诱导生成的碳酸钙晶体含量(CCC)、类型、比例以及MICP固化砂土力学强度等参数的影响规律,并结合扫描电镜(SEM)试验分析了溶液环境及砂柱中碳酸钙的微观形貌特征,系统归纳了Nano-Fe_(3)O_(4)对MICP的作用效果及机制。结果表明:(1)Nano-Fe_(3)O_(4)能够有效改善细菌的新陈代谢性能,显著提高细菌OD_(600)及脲酶活性;(2)溶液环境中,MICP产生的碳酸钙晶体类型以球霰石为主,含少量方解石,且Nano-Fe_(3)O_(4)含量增加能够促进球霰石的生成及增大MICP沉淀物中稳定相碳酸钙所占的比例;(3)Nano-Fe_(3)O_(4)可以显著提高MICP固化砂土的无侧限抗压强度和CCC;(4)SEM分析结果表明,溶液环境中,碳酸钙晶体以球型堆积为主,MICP固化砂柱中碳酸钙晶型随Nano-Fe_(3)O_(4)含量的增加逐渐呈菱柱状堆积。

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.

青海强盐渍粉砂土MICP的有效性探索

在极端环境中发现原生高产脲酶微生物并开展岩土体的固强研究,是岩土体微生物矿化研究的一个热点和难点。该文在青海柴达木地区的强盐渍土中发现一种新型原生高产脲酶微生物,在强盐环境中,试验该微生物的盐耐受性和矿化性能,开展被加固土体力学强度试验。结果表明:在强盐渍环境下,该新型微生物脲酶活性保持在3.02U~5.03U。在强盐渍粉砂土中进行微生物矿化试验,一周时间内,可以使盐渍粉砂土柱中的碳酸钙含量增加8.11%,碳酸钙主要以球霰石为主;土柱的孔隙率降低6.12%,孔径由4~40μm大孔隙为主,变为以0.4~4μm的中孔隙为主,孔径分布范围变小了65%~68%;土柱的基本力学强度指标值得到提升。研究表明:该新型原生高产脲酶微生物对青海强盐渍土环境具有良好的耐受性,经过对其矿化诱导,可以产生球霰石沉淀,并能有效地黏结盐渍土颗粒,实现对盐渍土固强的目的。研究提供了在强盐渍土中进行微生物提取和矿化固强的研究方法,为探索高盐极端环境岩土材料MICP的有效性,提供一种新思路。

加速微生物诱导碳酸盐沉淀过程的调控因子筛选及机理初步研究

微生物诱导碳酸盐沉淀(MICP)技术被广泛应用于土壤重金属污染控制中,然而,土壤的成分会降低碳酸钙成核速率,为解决其矿化过程成核慢、矿化产物晶型不稳定等问题,选取六种调控因子:柠檬酸钠(C_(6)H_(5)Na_(3)O_(7))、氧化镁(MgO)、氯化镁(MgCl_(2))、壳聚糖((C6H11NO4)n)、乙醇(C_(2)H_(5)OH)和二氧化硅(SiO_(2)),利用偏振光显微镜、扫描电子显微镜(SEM)、X射线衍射(XRD)及傅里叶红外光谱(FTIR)等测试手段和方法,筛选出能够加速结晶且生成沉淀量最多,对铅的去除率达到90%的调控因子柠檬酸钠(TKa)。结果表明,柠檬酸钠能稳定球霰石,加快矿化过程和增加矿化沉淀,提高重金属去除率。因此,柠檬酸钠具有提高MICP生物修复的速度,对提高MICP技术应用的效率具有重要意义。

基于微生物诱导碳酸钙沉积的生物覆膜防渗研究

针对水利工程防渗堵漏的问题,以降低砂土生物覆膜透水率、提高砂土胶结之后的强度为目的,利用巴氏芽孢杆菌催化尿素水解对MICP(microbially induced calcium carbonate precipitation)生物覆膜效果的影响因素展开试验研究。采用控制变量法探究胶结液浓度和胶结时间对生物覆膜效果的影响,从而为生物覆膜技术的实际应用提供基础性数据和科学依据。结果表明:相同胶结时间的情况下,胶结液浓度越大,钙离子利用率越高;生物覆膜样本的最小渗透系数为2.42×10-5cm/s,防渗效果相当于粉土或黏土混合物,最大抗折强度为1.63 MPa,最大抗压强度为1.5 MPa;胶结液浓度是影响覆膜抗折强度的主要因素,相同浓度下的胶结时间越长,对应的抗折强度值越大;碳酸钙在颗粒间的孔隙中充当胶凝作用,碳酸钙含量与抗折和抗压强度呈正相关关系。研究成果对未来将生物覆膜技术应用于水工防渗材料具有参考价值。