Your search keyword '"Kazunori Nakashima"' showing total 149 results

1. Ecofriendly solidification of sand using microbially induced calcium phosphate precipitation

Author

Maksym Avramenko, Kazunori Nakashima, Chikara Takano, and Satoru Kawasaki

Subjects

Soil improvement, Microbial induced calcium phosphate precipitation, Calcium phosphate compounds, Tuna fish bones, Lactic acid bacteria, Medicine, Science

Abstract

Abstract This study introduces microbiologically induced calcium phosphate precipitation (MICPP) as a novel and environmentally sustainable method of soil stabilization. Using Limosilactobacillus sp., especially NBRC 14511 and fish bone solution (FBS) extracted from Tuna fish bones, the study was aimed at testing the feasibility of calcium phosphate compounds (CPCs) deposition and sand stabilization. Dynamic changes in pH and calcium ion (Ca2+) concentration during the precipitation experiments affected the precipitation and sequential conversion of dicalcium phosphate dihydrate (DCPD) to hydroxyapatite (HAp), which was confirmed by XRD and SEM analysis. Sand solidification experiments demonstrated improvements in unconfined compressive strength (UCS), especially at higher Urea/Ca2+ ratios. The UCS values obtained were 10.35 MPa at a ratio of 2.0, 3.34 MPa at a ratio of 1.0, and 0.43 MPa at a ratio of 0.5, highlighting the advantages of MICPP over traditional methods. Microstructural analysis further clarified the mineral composition, demonstrating the potential of MICPP in environmentally friendly soil engineering. The study highlights the promise of MICPP for sustainable soil stabilization, offering improved mechanical properties and reducing environmental impact, paving the way for novel geotechnical practices.

Published

2024

2. Combination of cellulose nanofiber and artificial fusion protein for biocementation

Author

Thiloththama Hiranya Kumari Nawarathna, Jin Sakai, Kazunori Nakashima, Tetsuya Kawabe, Miki Shikama, Chikara Takano, and Satoru Kawasaki

Subjects

biocement, cellulose nanofiber, fusion protein, hybrid materials, calcium carbonate, Engineering (General). Civil engineering (General), TA1-2040, City planning, HT165.5-169.9

Abstract

Biomineralization occurring in living organisms is mostly controlled by organic macromolecules such as polysaccharides and proteins. Recently, biomineralization has been attracting much attention as a green and sustainable cementation technique including enzyme-induced carbonate precipitation (EICP), where CaCO3 is formed by hydrolysis of urea by urease in the presence of calcium ions. In this study, we have developed a novel hybrid biocementation method combining CaCO3 and cellulose nanofiber (CNF). In nature, matrix proteins work as a binder at the interface of organic and inorganic materials to form hybrid biomaterials. By mimicking the natural system, we designed an artificial fusion protein to facilitate the deposition of CaCO3 on CNF. Calcite-binding peptide (CaBP) and carbohydrate-binding module (CBM) were introduced in the artificial fusion protein CaBP-CBM to connect CaCO3 and cellulose. The addition of CNF in the EICP system resulted in the formation of a number of small particles of CaCO3 compared to a non-additive system. The addition of the fusion protein CaBP-CBM to CNF led to an increase in the size of CaCO3 particles. Furthermore, the combination of CaBP-CBM and CNF provides higher strength of samples in sand solidification. Therefore, introduction of CNF and the fusion protein would be promising for novel biocementation techniques.

Published

2024

3. Baseline investigation on enzyme induced calcium phosphate precipitation for solidification of sand

Author

Sivakumar Gowthaman, Moeka Yamamoto, Meiqi Chen, Kazunori Nakashima, and Satoru Kawasaki

Subjects

bio-cementation, enzyme induced calcium phosphate precipitation (EICPP), urea hydrolysis, cementation media, PH dependency, brushite, Engineering (General). Civil engineering (General), TA1-2040, City planning, HT165.5-169.9

Abstract

Introduction: Bio-cementation processes [namely, microbial induced carbonate precipitation (MICP) and enzyme induced carbonate precipitation (EICP)] have recently become promising techniques for solidifying loose sands. However, these methods release gaseous ammonia to the atmosphere, which is not desirable for real-scale applications. This study aims to propose an enzyme induced calcium phosphate precipitation (EICPP) method as a sustainable direction for the solidification of sand.Methods: Precipitation of calcium phosphate compound (CPC) was driven through pH-dependent mechanism regulated by enzymatic hydrolysis of urea. The baseline study was designed to consist of a series of precipitation tests and sand column tests, evaluating the influence of various recipes of cementation media (CM) on treatment efficiency. The evaluation program consisted of Unconfined compression tests, precipitation content measurement, scanning electron microscopy (SEM), energy-dispersive X-ray spectroscopy (EDS) and X-ray diffraction.Results: The observations showed that the content of urea had an important role in proposed EICPP treatment, which determined the extent of the pH increase. This increase had a great influence on 1) utilization of soluble calcium, 2) precipitation content of calcium phosphate, and 3) the morphology of the precipitates. Results of sand column test suggested that injecting CM that consisted of acid-dissolved bone meal, urea and urease enzyme could result in the deposition of insoluble CPC that enabled the solidification of sand particles.Discussion: The precipitation quantity was found to increase with the increase in urea content; however, the treatment media with high urea content resulted amorphous-like crystals. The plate-like crystals were evidenced in CM with [Ca]/[urea] molar ratio between 1.5–2.0. X-ray Diffraction (XRD) analysis revealed that irrespective of the urea contents, the formed crystals were identified as brushite. Since the final pH of proposed EICPP method could be controllable within acidic-neutral conditions, the emission of ammonia gas would be eliminated.

Published

2023

4. Biomineralization Grouting for Beach Sand Cemented with MICP

Author

Lutfian Rusdi Daryono, Sonoko Aoki, Masanao Kano, Mimori Miyanaga, Kazunori Nakashima, and Satoru Kawasaki

Subjects

Coastal, Erosion, MICP, Biomineral, Durability, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Microbial-induced carbonate precipitation (MICP) is an environmentally friendly approach that relies on the production of calcium carbonate by microorganisms to construct or reinforce coastal structures. In order to address the disadvantages of current coastal countermeasures techniques, MICP is a cost-effective solution that can be used to repair and restore coastal habitats damaged by human activities. The resulting structures formed through MICP are strong and durable, providing long-term protection against erosion and flooding caused by storms or rising sea levels. Biominerals, including calcium carbonate or calcium phosphate, are used to create complex composites with organic molecules by combining the strength of inorganic materials with the versatility and biocompatibility of organic macromolecules. It is of the utmost importance to investigate the functionality of MICP and scale up its deployment in various fields in order to thoroughly assess the instrument’s application. Coastal erosion has been a severe concern in archipelagic countries. Therefore, this study explored the Miyazaki coast in Japan and the Yogyakarta coastline in Indonesia to minimize coastal erosion using MICP. The bacteria found in Miyazaki (Sporosarcina species) and the Yogyakarta coast (Pseudoalteromonas tetradonis) were used in the experiment. As a result, the sample treated with a gradual injection of the cementation solution achieved about 6 MPa UCS after 21 days of treatment. The objective were investigated the potential biotreatment with original sand materials and to evaluate the long-term durability under saturated conditions. For these purposes, the MICP-treated sand columns were subjected to series of compression tests and wet-drying (WD) durability analysis.

Published

2023

5. Field experimentation of bio-cementation using low-cost cementation media for preservation of slope surface

Author

Sivakumar Gowthaman, Hiromu Koizumi, Kazunori Nakashima, and Satoru Kawasaki

Subjects

Microbial induced carbonate precipitation (MICP), Cementation media, Low-grade chemicals, Analytical-grade chemicals, Slope surface, Field-scale, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Microbial induced carbonate precipitation (MICP) is a promising bio-cementation method that involves ureolytic bacteria to improve the geotechnical properties of soil. The laboratory-scale studies carried out in the recent past showed that the MICP can be a potential alternative for slope surface preservation. However, the use of analytical-grade chemicals makes this method too expensive, limiting the applicability of the method especially when implicated at field-scale. The purpose of this research work was to assess the effectiveness of using inexpensive low-grade chemicals for the in-situ stabilization of slope surface. Two test plots were established at the project site (Hokkaido expressway slope, Japan) and subjected to MICP treatment via surficial spraying. One was treated using the cementation media formulated by low-grade chemicals (inclusive of fertilizer urea, snow-melting agent and beer-yeast), while the typical analytical-grade media was used to treat the other plot. After 20 days of treatment, the treated slope surfaces were evaluated by surface strength, CaCO3 content, scanning electron microscopy, energy dispersive spectroscopy (EDS) and X-ray diffraction (XRD) analyses. The outcomes indicated that the surface was significantly improved by low-grade chemicals; a stiff surface layer was desirably formed to the depth of 5 – 10 cm with the surface strength and CaCO3 content in the ranges of 0.14 – 1.02 MPa and 0.56 – 3.7%, respectively. The results are compared and discussed, and the challenges in the use of low-grade chemicals are pointed out for the way forward. Cost analysis disclosed that the material cost of the cementation media was reduced by around thirty-seven-fold (by 97%) compared to the analytical-grade media. While demonstrating the potential use of low-grade chemicals, the field-scale experiment could contribute to narrow down the gap between the present-state and real-scale deployment of MICP technology.

Published

2023

6. Baseline investigation on soil solidification through biocementation using airborne bacteria

Author

Meiqi Chen, Sivakumar Gowthaman, Kazunori Nakashima, Chikara Takano, and Satoru Kawasaki

Subjects

airborne bacteria, microbial induced carbonate precipitation, urease activity, bacterial identification, unconfined compressive strength, Biotechnology, TP248.13-248.65

Abstract

Microbial induced carbonate precipitation (MICP) through the ureolysis metabolic pathway is one of the most studied topics in biocementation due to its high efficiency. Although excellent outcomes have proved the potential of this technique, microorganisms face some obstacles when considering complicated situations in the real field, such as bacterial adaptability and survivability issues. This study made the first attempt to seek solutions to this issue from the air, exploring ureolytic airborne bacteria with resilient features to find a solution to survivability issues. Samples were collected using an air sampler in Sapporo, Hokkaido, a cold region where sampling sites were mostly covered with dense vegetation. After two rounds of screening, 12 out of 57 urease-positive isolates were identified through 16S rRNA gene analysis. Four potentially selected strains were then evaluated in terms of growth pattern and activity changes within a range of temperatures (15°C–35°C). The results from sand solidification tests using two Lederbergia strains with the best performance among the isolates showed an improvement in unconfined compressive strength up to 4–8 MPa after treatment, indicating a high MICP efficiency. Overall, this baseline study demonstrated that the air could be an ideal isolation source for ureolytic bacteria and laid a new pathway for MICP applications. More investigations on the performance of airborne bacteria under changeable environments may be required to further examine their survivability and adaptability.

Published

2023

7. Polymer-assisted enzyme induced carbonate precipitation for non-ammonia emission soil stabilization

Author

Zhen Yan, Sivakumar Gowthaman, Kazunori Nakashima, and Satoru Kawasaki

Subjects

Medicine, Science

Abstract

Abstract Biocementation using enzyme induced carbonate precipitation (EICP) process has become an innovative method for soil improvement. One of the major limitations in scaling-up of biocement treatment is the emission of gaseous ammonia during the urea hydrolysis, which is environmentally hazardous. In order to eliminate this shortcoming, this paper presents a series of experiments performed to evaluate a novel approach for preventing the ammonia byproducts in the EICP process via the use of polyacrylic acid (PAA). Through the adjustment of the pH to acidic, PAA not only promotes the enzyme activity, but also averts the conversion of ammonium to gaseous ammonia and its release, thus preventing any harm to the environment. The sand samples were treated with cementation solution and assessed for improvement in strength. Calcium carbonate content measurements and X-ray powder diffraction analysis identified the calcite crystals precipitated in the soil pores. Scanning electron microscopy analysis clearly showed that calcium carbonate was precipitated connecting soil particles, thus providing a uniaxial compressive strength (UCS) of up to 1.65 MPa. Overall, the inhibition in the speciation of gaseous ammonia shows the great potential of PAA for large-scale promotion of biocement.

Published

2022

8. Feasibility of bacterial-enzyme induced carbonate precipitation technology for stabilizing fine-grained slope soils

Author

Sivakumar Gowthaman, Takashi Iki, Aoi Ichinohe, Kazunori Nakashima, and Satoru Kawasaki

Subjects

microbial induced carbonate precipitation, bacterial-enzyme induced carbonate precipitation, free urease, fine-grained soil, slope surface, cementation, Engineering (General). Civil engineering (General), TA1-2040, City planning, HT165.5-169.9

Abstract

Microbial Induced Carbonate Precipitation (MICP) has recently become a new technology for stabilizing the slope surface. The applicability of MICP, however, is limited in fine-grained soils due to the restrictions regarding the transportation of bacteria cells. The purpose of this study was to assess the feasibility of an alternative called Bacterial-Enzyme Induced Carbonate Precipitation (B-EICP) for stabilizing the fine-grained slope soils. Unlike the MICP strategy (involving whole-cells of bacteria), the proposed B-EICP utilizes bacterial urease to induce the bio-cement formation within soil. The whole-cell culture of Lysinibacillus xylanilyticus was subjected to cyclic sonication to extract the free urease suspension. The B-EICP treatment was performed to the columns prepared using two different soils obtained from representative expressway slopes. The cementation responses of the proposed B-EICP were compared with that of typical MICP method, especially from the following viewpoints, (i) adaptability to soil with high fine-grained content, (ii) conditions under which B-EICP can be effectively applied and (iii) cementation under low temperature. The results revealed that the extract solution had higher urease activity compared to original bacteria culture, and the activity remained more stable at low temperature conditions (15°C). The results further confirmed that B-EICP method is more suitable for stabilizing soils with large amount of fine particles. Comparing with MICP, the B-EICP resulted higher unconfined compressive strength (over 1200 kPa) and deeper cementation in the silty sand. Microscale analysis suggested that the B-EICP could induce smaller calcium carbonate crystals than that by MICP, but the number of crystals in B-EICP were significantly more, thus contributed to increased particle-particle cementation.

Published

2022

9. Naturally Derived Cements Learned from the Wisdom of Ancestors: A Literature Review Based on the Experiences of Ancient China, India and Rome

Author

Zhan Su, Zhen Yan, Kazunori Nakashima, Chikara Takano, and Satoru Kawasaki

Subjects

naturally derived cement, Portland cement, enzyme-induced carbonate precipitation (EICP), microbially induced carbonate precipitation (MICP), Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

For over a thousand years, many ancient cements have remained durable despite long-term exposure to atmospheric or humid agents. This review paper summarizes technologies of worldwide ancient architectures which have shown remarkable durability that has preserved them over thousands of years of constant erosion. We aim to identify the influence of organic and inorganic additions in altering cement properties and take these lost and forgotten technologies to the production frontline. The types of additions were usually decided based on the local environment and purpose of the structure. The ancient Romans built magnificent structures by making hydraulic cement using volcanic ash. The ancient Chinese introduced sticky rice and other local materials to improve the properties of pure lime cement. A variety of organic and inorganic additions used in traditional lime cement not only changes its properties but also improves its durability for centuries. The benefits they bring to cement may also be useful in enzyme-induced carbonate precipitation (EICP) and microbially induced carbonate precipitation (MICP) fields. For instance, sticky rice has been confirmed to play a crucial role in regulating calcite crystal growth and providing interior hydrophobic conditions, which contribute to improving the strength and durability of EICP- and MICP-treated samples in a sustainable way.

Published

2023

10. State-of-the-Art Review on Engineering Uses of Calcium Phosphate Compounds: An Eco-Friendly Approach for Soil Improvement

Author

Maksym Avramenko, Kazunori Nakashima, and Satoru Kawasaki

Subjects

novel grout material, soil improvement, sustainable geotechnics, calcium phosphate compounds (CPCs), calcium phosphate precipitation, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Greenhouse gas emissions are a critical problem nowadays. The cement manufacturing sector alone accounts for 8% of all human-generated emissions, and as the world’s population grows and globalization intensifies, this sector will require significantly more resources. In order to fulfill the need of geomaterials for construction and to reduce carbon dioxide emissions into the atmosphere, conventional approaches to soil reinforcement need to be reconsidered. Calcium phosphate compounds (CPCs) are new materials that have only recently found their place in the soil reinforcement field. Its eco-friendly, non-toxic, reaction pathway is highly dependent on the pH of the medium and the concentration of components inside the solution. CPCs has advantages over the two most common environmental methods of soil reinforcement, microbial-induced carbonate precipitation (MICP) and enzyme induced carbonate precipitation (EICP); with CPCs, the ammonium problem can be neutralized and thus allowed to be applied in the field. In this review paper, the advantages and disadvantages of the engineering uses of CPCs for soil improvement have been discussed. Additionally, the process of how CPCs perform has been studied and an analysis of existing studies related to soil reinforcement by CPC implementation was conducted.

Published

2022

11. Effect of Scallop Powder Addition on MICP Treatment of Amorphous Peat

Author

Sivakumar Gowthaman, Meiqi Chen, Kazunori Nakashima, and Satoru Kawasaki

Subjects

microbial-induced carbonate precipitation (MICP), amorphous peat, scallop shell powder, stabilization, unconfined compressive strength, Environmental sciences, GE1-350

Abstract

Peat is one of the most challenging and problematic soils in the fields of geotechnical and environmental engineering. The most critical problems related to peat soils are extremely low strength and high compressibility, resulting in poor inhabitancy and infrastructural developments in their vicinity. Thus far, peat soils were stabilized using Portland cement; however, the production of Portland cement causes significant emission of greenhouse gases, which is not environmentally desirable. Microbial-induced carbonate precipitation (MICP) is an innovative technique for improving the mechanical properties of soil through potentially environmentally friendly processes. This article presents a laboratory study carried out with the aim of investigating the viability and effect of scallop shell powder (SSP) on enhancing the mechanical properties of the MICP-treated amorphous peat. The hypothesis was that the distribution of SSP (as-derived calcite particles) would (i) provide more nucleation sites to precipitates and (ii) increase the connectivity of MICP bridges to facilitate mineral skeleton to amorphous peat, accompanied by an increase in its compressive strength. Specimens were treated at varying combinations of SSP and MICP reagents, and the improvement was comprehensively assessed through a series of unconfined compression tests and supported by microscale and chemical analyses such as scanning electron microscopy, energy-dispersive X-ray analysis, and X-ray diffraction analysis. The outcomes showed that incorporating SSP in MICP treatment would be a promising approach to treat amorphous peat soils. The proposed approach could improve the unconfined compressive strength by over 200% after a 7-day curing period, while the conventional MICP could not exhibit any significant improvements.

Published

2021

12. Durability Improvement of Biocemented Sand by Fiber-Reinforced MICP for Coastal Erosion Protection

Author

Md Al Imran, Kazunori Nakashima, Niki Evelpidou, and Satoru Kawasaki

Subjects

MICP, jute fiber, durability, soil improvement, biocement, fiber reinforcement, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Soil improvement via MICP (microbially induced carbonate precipitation) technologies has recently received widespread attention in the geoenvironmental and geotechnical fields. The durability of MICP-treated samples remains a critical concern in this novel method. In this work, fiber (jute)-reinforced MICP-treated samples were investigated to evaluate their durability under exposure to distilled water (DW) and artificial seawater (ASW), so as to advance the understanding of long-term performance mimicking real field conditions, along with improvement of the MICP-treated samples for use in coastal erosion protection. Primarily, the results showed that the addition of fiber (jute) improved the durability of the MICP-treated samples by more than 50%. Results also showed that the wet–dry (WD) cyclic process resulted in adverse effects on the mechanical and physical characteristics of fiber-reinforced MICP-treated samples in both DW and ASW. The breakdown of calcium carbonates and bonding effects in between the sand particles was discovered to be involved in the deterioration of MICP samples caused by WD cycles, and this occurs in two stages. The findings of this study would be extremely beneficial to extend the insight and understanding of improvement and durability responses for significant and effective MICP treatments and/or re-treatments.

Published

2022

13. Electricity Generation from Rice Bran by a Microbial Fuel Cell and the Influence of Hydrodynamic Cavitation Pretreatment

Author

Yuta Yoshimura, Kazunori Nakashima, Masaji Kato, Kengo Inoue, Fumiyoshi Okazaki, Hitoshi Soyama, and Satoru Kawasaki

Subjects

Chemistry, QD1-999

Published

2018

14. Experimental Study on Sand Stabilization Using Bio-Cementation with Wastepaper Fiber Integration

Author

Meiqi Chen, Sivakumar Gowthaman, Kazunori Nakashima, Shin Komatsu, and Satoru Kawasaki

Subjects

microbially-induced carbonate precipitation (MICP), wastepaper fiber, mechanical properties, calcium carbonate, freeze-thaw durability, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Recently, green materials and technologies have received considerable attention in geotechnical engineering. One of such techniques is microbially-induced carbonate precipitation (MICP). In the MICP process, CaCO3 is achieved bio-chemically within the soil, thus enhancing the strength and stiffness. The purpose of this study is to introduce the wastepaper fiber (WPF) onto the MICP (i) to study the mechanical properties of MICP-treated sand with varying WPF content (0–8%) and (ii) to assess the freeze–thaw (FT) durability of the treated samples. Findings revealed that the ductility of the treated samples increases with the increase in WPF addition, while the highest UCS is found with a small fiber addition. The results of CaCO3 content suggest that the WPF addition enhances the immobilization of the bacteria cells, thus yielding the precipitation content. However, shear wave velocity analysis indicates that a higher addition of WPF results in rapid deterioration of the samples when subjected to freeze–thaw cycles. Microscale analysis illuminates that fiber clusters replace the solid bonding at particle contacts, leading to reduced resistance to freeze–thaw damage. Overall, the study demonstrates that as a waste material, WPF could be sustainably reused in the bio-cementation.

Published

2021

15. Bio-Mediated Soil Improvement Using Plant Derived Enzyme in Addition to Magnesium Ion

Author

Md Al Imran, Kazunori Nakashima, and Satoru Kawasaki

Subjects

enzyme-induced carbonate precipitation (EICP), urease activity, Mg2+/Ca2+ ratios, watermelon seeds, CaCO3 morphology, soil improvement, Crystallography, QD901-999

Abstract

Recently, soil improvement using EICP (Enzyme-Induced Carbonate Precipitation) methods in the geotechnical and geo-environmental field has become a prominent interest worldwide. The objective of this study was to develop an improved extraction technique of crude urease from watermelon seeds in both dry and germinated conditions. Subsequently, this study also analyzed the improvement methodology of crystal polymorphs and soil bonding incorporation of various Mg2+/Ca2+ ratios. The optimization of enzyme-mediated carbonate precipitation was also investigated by Scanning Electron Microscope (SEM) and X-ray Diffraction (XRD) analysis. Results confirmed that the precipitated crystals are mainly calcite, vaterite and aragonite primarily (depending on the Mg2+/Ca2+ ratios). Therefore, to improve the bonding capacity in between the sand particles a novel improvement methodology was investigated by adding various Mg2+/Ca2+ ratios. The mechanical properties of the treated soil (Mikawa Sand, D50 = 0.870 mm) specimens were tested by unconfined compressive strength (UCS) and this confirmed the effectiveness of adding various Mg2+/Ca2+ ratios. The results of the UCS tests showed that, the lower molar ratios of Mg2+/Ca2+ can significantly improve the UCS of the specimen (up to 50%) which could be considered a significant outcome for different bio-geotechnical applications.

Published

2021

16. The Influence of the Addition of Plant-Based Natural Fibers (Jute) on Biocemented Sand Using MICP Method

Author

Md Al Imran, Sivakumar Gowthaman, Kazunori Nakashima, and Satoru Kawasaki

Subjects

jute, MICP, ureolytic bacteria, biocement, natural plant fiber, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

The microbial-induced carbonate precipitation (MICP) method has gained intense attention in recent years as a safe and sustainable alternative for soil improvement and for use in construction materials. In this study, the effects of the addition of plant-based natural jute fibers to MICP-treated sand and the corresponding microstructures were measured to investigate their subsequent impacts on the MICP-treated biocemented sand. The fibers used were at 0%, 0.5%, 1.5%, 3%, 5%, 10%, and 20% by weight of the sand, while the fiber lengths were 5, 15, and 25 mm. The microbial interactions with the fibers, the CaCO3 precipitation trend, and the biocemented specimen (microstructure) were also evaluated based on the unconfined compressive strength (UCS) values, scanning electron microscopy (SEM), and fluorescence microscopy. The results of this study showed that the added jute fibers improved the engineering properties (ductility, toughness, and brittleness behavior) of the biocemented sand using MICP method. Furthermore, the fiber content more significantly affected the engineering properties of the MICP-treated sand than the fiber length. In this study, the optimal fiber content was 3%, whereas the optimal fiber length was s 15 mm. The SEM results indicated that the fiber facilitated the MICP process by bridging the pores in the calcareous sand, reduced the brittleness of the treated samples, and increased the mechanical properties of the biocemented sand. The results of this study could significantly contribute to further improvement of fiber-reinforced biocemented sand in geotechnical engineering field applications.

Published

2020

17. Investigation of Natural Beachrock and Physical–Mechanical Comparison with Artificial Beachrock Induced by MICP as a Protective Measure against Beach Erosion at Yogyakarta, Indonesia

Author

Lutfian R. Daryono, Kazunori Nakashima, Satoru Kawasaki, Koichi Suzuki, Imam Suyanto, and Arief Rahmadi

Subjects

beachrock, resistivity, MASW, physical properties, mechanical properties, microbial-induced carbonate precipitation, Geology, QE1-996.5

Abstract

Typically, the mitigation of coastal erosion is achieved by amending surface conditions using materials, such as concrete. The objective of this study is to evaluate the feasibility of constructing artificial beachrocks using natural materials (e.g., microbes, sand, shell, pieces of coral, and seaweed, etc.) within a short time, and to propose the method as a novel strategy for coastal protection. Initially, a survey on resistivity and a multichannel analysis of seismic waves (MASW) were conducted along the coastal lines to characterize and elucidate the subsurface structure of existing beachrocks in the Southeast Yogyakarta coastal area, Krakal–Sadranan beach, Indonesia. The field survey on natural beachrocks suggested that both resistivity and shear wave velocity were higher in the deeper deposits compared to the underlying unconsolidated sand layer within a depth of approximately 1.5 m and covering an area of 210.496 m2 for the α-section and 76.936 m2 for the β-section of beachrock deposit. The results of the sand solidification test in the laboratory showed that treated sand achieved unconfined compressive strength of up to around 6 MPa, determined after a treatment period of 14 days under optimum conditions.

Published

2020

18. Sediment Characteristics of Beachrock: A Baseline Investigation Based on Microbial Induced Carbonate Precipitation at Krakal-Sadranan Beach, Yogyakarta, Indonesia

Author

Lutfian Rusdi Daryono, Kazunori Nakashima, Satoru Kawasaki, Anastasia Dewi Titisari, and Didit Hadi Barianto

Subjects

ureolytic bacteria, isolation, diagenetic process, beachrock, microbial, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Isolation of ureolytic bacteria and geochemical analysis of beachrock from Krakal-Sadranan Beach (Yogyakarta, Indonesia) were conducted to determine natural sedimentary characteristics of the beachrock. The beachrock was also examined to determine the depositional conditions and distribution of rare earth elements. An increased concentration of total rare earth elements, both heavy rare earth elements (terbium, dysprosium, yttrium, holmium, erbium, thulium, ytterbium, and lutetium) and light rare earth elements (lanthanum, cesium, praseodymium, neodymium, samarium, europium, and gadolinium) signals that the beachrock deposition process happened under oxidative environmental conditions. This study proposes the novel use of ureolytic bacteria in a depositional environment for carbonate control of a sedimentary process for the development of artificial rock to mitigate coastal erosion. The resulting bacterial strains are highly homologous to the 16S rDNA nucleotide sequence of the species Oceanobacillus profundus, Vibrio maritimus, and Pseudoalteromonas tetradonis.

Published

2020

19. Feasibility Study of Native Ureolytic Bacteria for Biocementation Towards Coastal Erosion Protection by MICP Method

Author

Md Al Imran, Shuya Kimura, Kazunori Nakashima, Niki Evelpidou, and Satoru Kawasaki

Subjects

microbially induced carbonate precipitation, ureolytic bacteria, urease activity, biomineralization, coastal erosion protection, artificial beachrock, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

In recent years, traditional material for coastal erosion protection has become very expensive and not sustainable and eco-friendly for the long term. As an alternative countermeasure, this study focused on a sustainable biological ground improvement technique that can be utilized as an option for improving the mechanical and geotechnical engineering properties of soil by the microbially induced carbonate precipitation (MICP) technique considering native ureolytic bacteria. To protect coastal erosion, an innovative and sustainable strategy was proposed in this study by means of combing geotube and the MICP method. For a successful sand solidification, the urease activity, environmental factors, urease distribution, and calcite precipitation trend, among others, have been investigated using the isolated native strains. Our results revealed that urease activity of the identified strains denoted as G1 (Micrococcus sp.), G2 (Pseudoalteromonas sp.), and G3 (Virgibacillus sp.) relied on environment-specific parameters and, additionally, urease was not discharged in the culture solution but would discharge in and/or on the bacterial cell, and the fluid of the cells showed urease activity. Moreover, we successfully obtained solidified sand bearing UCS (Unconfined Compressive Strength) up to 1.8 MPa. We also proposed a novel sustainable approach for field implementation in a combination of geotube and MICP for coastal erosion protection that is cheaper, energy-saving, eco-friendly, and sustainable for Mediterranean countries, as well as for bio-mediated soil improvement.

Published

2019

20. Microbial Induced Carbonate Precipitation Using a Native Inland Bacterium for Beach Sand Stabilization in Nearshore Areas

Author

Pahala Ge Nishadi Nayanthara, Anjula Buddhika Nayomi Dassanayake, Kazunori Nakashima, and Satoru Kawasaki

Subjects

beach sand stabilization, coastal erosion, local ureolytic bacterium, microbial induced carbonate precipitation, crystal morphology, nearshore areas, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Microbial Induced Carbonate Precipitation (MICP) via urea hydrolysis is an emerging sustainable technology that provides solutions for numerous environmental and engineering problems in a vast range of disciplines. Attention has now been given to the implementation of this technique to reinforce loose sand bodies in-situ in nearshore areas and improve their resistance against erosion from wave action without interfering with its hydraulics. A current study has focused on isolating a local ureolytic bacterium and assessed its feasibility for MICP as a preliminary step towards stabilizing loose beach sand in Sri Lanka. The results indicated that a strain belonging to Sporosarcina sp. isolated from inland soil demonstrated a satisfactory level of enzymatic activity at 25 °C and moderately alkaline conditions, making it a suitable candidate for target application. Elementary scale sand solidification test results showed that treated sand achieved an approximate strength of 15 MPa as determined by needle penetration device after a period of 14 days under optimum conditions. Further, Scanning Electron Microscopy (SEM) imagery revealed that variables such as grain size distribution, bacteria population, reactant concentrations and presence of other cations like Mg2+ has serious implications on the size and morphology of precipitated crystals and thus the homogeneity of the strength improvement.

Published

2019

21. A State-of-the-Art Review on Soil Reinforcement Technology Using Natural Plant Fiber Materials: Past Findings, Present Trends and Future Directions

Author

Sivakumar Gowthaman, Kazunori Nakashima, and Satoru Kawasaki

Subjects

natural fibers, synthetic material, biochemical properties, sustainable geotechnics, oriented distributed fiber-reinforced soil (ODFS), randomly distributed fiber-reinforced soil (RDFS), Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Incorporating sustainable materials into geotechnical applications increases day by day due to the consideration of impacts on healthy geo-environment and future generations. The environmental issues associated with conventional synthetic materials such as cement, plastic-composites, steel and ashes necessitate alternative approaches in geotechnical engineering. Recently, natural fiber materials in place of synthetic material have gained momentum as an emulating soil-reinforcement technique in sustainable geotechnics. However, the natural fibers are innately different from such synthetic material whereas behavior of fiber-reinforced soil is influenced not only by physical-mechanical properties but also by biochemical properties. In the present review, the applicability of natural plant fibers as oriented distributed fiber-reinforced soil (ODFS) and randomly distributed fiber-reinforced soil (RDFS) are extensively discussed and emphasized the inspiration of RDFS based on the emerging trend. Review also attempts to explore the importance of biochemical composition of natural-fibers on the performance in subsoil reinforced conditions. The treatment methods which enhances the behavior and lifetime of fibers, are also presented. While outlining the current potential of fiber reinforcement technology, some key research gaps have been highlighted at their importance. Finally, the review briefly documents the future direction of the fiber reinforcement technology by associating bio-mediated technological line.

Published

2018

22. Feasibility study of enhancing enzyme-induced carbonate precipitation with eggshell waste for sand solidification.

Author

Zhen Yan, Kazunori Nakashima, Chikara Takano, and Satoru Kawasaki

Subjects

CALCIUM carbonate, EGGSHELLS, SOLIDIFICATION, CALCIUM ions, NUCLEATION, WASTE recycling

Abstract

Utilizing Enzyme-Induced Calcium Carbonate Precipitation (EICP) reinforcement technology has emerged as an innovative approach for soil improvement. In this study, kitchen waste eggshell powder was used as an additive material for EICP. The high external surface area and affinity for calcium ions of eggshell powder, which render it a suitable nucleation site for calcium carbonate precipitation. Experimental results demonstrate that the incorporation of eggshell powder, by increasing the number of nucleation sites and promoting calcium carbonate precipitation, reduces the inhibition of enzyme products, modulates the precipitation pattern of calcium carbonate, improves particle size distribution, and consequently significantly enhances the unconfined compressive strength of the samples. Furthermore, a neutral pH is achieved within the reaction system without the addition of any acid, thus preventing significant ammonia emissions. This underscores the potential of kitchen waste eggshells for recycling in biocement applications. [ABSTRACT FROM AUTHOR]

Published

2024

23. Interfacial biosilica coating of chitosan gel using fusion silicatein to fabricate robust hybrid material for biomolecular applications

Author

Kasun Godigamuwa, Kazunori Nakashima, Sota Tsujitani, Ryo Naota, Ilham Maulidin, and Satoru Kawasaki

Subjects

Biomedical Engineering, General Materials Science, General Chemistry, General Medicine

Abstract

An enzyme-encapsulated silica-based hybrid material was developed using a chitosan gel. Fusion silicatein (InaKC-ChBD-Sil), silicatein fused with a soluble tag and chitin-binding domain, was employed as an interfacial catalyst to form silica on a chitosan gel matrix under physiological conditions, and horseradish peroxidase was immobilised on the hybrid material. Silica formation on the gel was verified via fluorescence microscopy using a designed fusion protein called TBP-mCherry, a fluorescent protein fused with a silica-binding peptide. We report a chitosan gel-silica hybrid material capable of encapsulating enzymes for biomedical and environmental applications.

Published

2023

24. Influence of humic acid on microbial induced carbonate precipitation for organic soil improvement

Author

Meiqi Chen, Kazunori Nakashima, Satoru Kawasaki, and Sivakumar Gowthaman

Subjects

Health, Toxicology and Mutagenesis, Environmental Chemistry, General Medicine, Pollution

Abstract

Microbial induced carbonate precipitation (MICP) is one of the most commonly researched topics on biocementation, which achieves cementation of soil particles by carbonate from urea hydrolysis catalyzed by microbial urease. Although most MICP studies are limited to stabilizing sandy soils, more researchers are now turning their interest to other weak soils, particularly organic soils. To stabilize organic soils, the influence of humic substances should be investigated since it has been reported to inhibit urease activity and disrupt the formation of calcium carbonate. This study investigates the effect of humic acid (HA), one fraction of humic substances, on MICP. For this purpose, the effects of HA content on CaCO

Published

2022

25. Biomineralization Grouting for Beach Sand Cemented with MICP.

Author

Daryono, Lutfian Rusdi, Sonoko Aoki, Masanao Kano, Mimori Miyanaga, Kazunori Nakashima, and Satoru Kawasaki

Subjects

BIOMINERALIZATION, COASTAL changes, GROUTING, HUMAN settlements, CALCIUM carbonate, FLOOD damage prevention, SAND, COASTAL wetlands, EROSION

Abstract

Microbial-induced carbonate precipitation (MICP) is an environmentally friendly approach that relies on the production of calcium carbonate by microorganisms to construct or reinforce coastal structures. In order to address the disadvantages of current coastal countermeasures techniques, MICP is a cost-effective solution that can be used to repair and restore coastal habitats damaged by human activities. The resulting structures formed through MICP are strong and durable, providing long-term protection against erosion and flooding caused by storms or rising sea levels. Biominerals, including calcium carbonate or calcium phosphate, are used to create complex composites with organic molecules by combining the strength of inorganic materials with the versatility and biocompatibility of organic macromolecules. It is of the utmost importance to investigate the functionality of MICP and scale up its deployment in various fields in order to thoroughly assess the instrument's application. Coastal erosion has been a severe concern in archipelagic countries. Therefore, this study explored the Miyazaki coast in Japan and the Yogyakarta coastline in Indonesia to minimize coastal erosion using MICP. The bacteria found in Miyazaki (Sporosarcina species) and the Yogyakarta coast (Pseudoalteromonas tetradonis) were used in the experiment. As a result, the sample treated with a gradual injection of the cementation solution achieved about 6 MPa UCS after 21 days of treatment. The objective were investigated the potential biotreatment with original sand materials and to evaluate the long-term durability under saturated conditions. For these purposes, the MICP-treated sand columns were subjected to series of compression tests and wet-drying (WD) durability analysis. [ABSTRACT FROM AUTHOR]

Published

2024

26. Functional modification of mussel adhesive protein to control solubility and adhesion property

Author

Anju Pilakka Veedu, Kazunori Nakashima, Hayahide Shiga, Takahiro Sato, Kasun Godigamuwa, Naoki Hiroyoshi, and Satoru Kawasaki

Subjects

Bioengineering, Applied Microbiology and Biotechnology, Biotechnology

Published

2023

27. Solubilization and aggregation control of silica-polymerizing enzyme fused with a removable soluble protein

Author

Hidetoshi Oguri, Kazunori Nakashima, Kasun Godigamuwa, Junnosuke Okamoto, Yudai Takeda, Fumiyoshi Okazaki, Masafumi Sakono, and Satoru Kawasaki

Subjects

Bioengineering, Silicon Dioxide, Applied Microbiology and Biotechnology, Biotechnology

Abstract

Silicatein, a silica-polymerizing enzyme, is an attractive and promising biocatalyst in many applications such as the synthesis of bio-functionalized inorganic materials under mild conditions. However, its unfavorable aggregation in aqueous media due to its intermolecular hydrophobic interactions causes difficulties in handling and applications. This study aimed to enhance the solubility of silicatein via fusion with a small soluble protein, ProS2. ProS2-Sil showed high solubility and stability in aqueous media for more than 24 h. The aggregation property of ProS2-silicatein fusion protein (ProS2-Sil) was investigated with and without cleavage of ProS2 tag by site-specific protease. When ProS2 tag was removed, silicatein became aggregated, which was analyzed by transmission electron microscope and fluorescence microscope. ProS2-Sil and mature silicatein showed similar activities in silica polymerization. The present approach allows the utilization of silicatein in the fabrication of novel and functional inorganic biohybrid materials.

Published

2022

28. Removal of ammonium by-products from the effluent of bio-cementation system through struvite precipitation

Author

Sivakumar Gowthaman, Kazunori Nakashima, Satoru Kawasaki, and Arash Mohsenzadeh

Subjects

chemistry.chemical_compound, Calcium carbonate, chemistry, Precipitation (chemistry), Struvite, Cementation (metallurgy), Urea, Carbonate, Ammonium, Pulp and paper industry, Effluent

Abstract

Microbial induced carbonate precipitation (MICP) (also referred to as bio-cementation) is an innovative soil improvement technology, introduced through Bio-mediated Geotechnics. During the process, supplied microorganisms hydrolyze urea, resulting in the formation of calcium carbonate. The precipitates tend to cement the soil particles at particle contacts and enhance the strength of the matrix. Despite the considerable interests in MICP, one major hurdle that hinders the field-scale applications is related to the production of ammonium during the process. The objective of this study is to evaluate the feasibility of struvite (NH4MgPO4·6H2O) precipitation to eliminate the ammonium from the reaction effluent system. For this purpose, the study is considered in two stages: (i) rinsing the ammonium from the sand, and (ii) precipitating ammonium as struvite. In the first-stage, the conditions of rinsing are studied to optimize the removal of ammonium from the soil. In the second-stage, influences of pH conditions, molar ratio and calcium ions on the precipitation of struvite are evaluated. The study demonstrates, through the struvite precipitation technique, around 90% of ammonium could be removed from the effluent. Finding also suggests that the molar ratio (NH4+: Mg2+: PO43-) of 1: 1.2: 1 provides a desirable environment for appropriate removal.

Published

2022

29. Experimental Study on Eco-Friendly Soil Stabilization Method Using Fish Bone as Cement Material

Author

Maksym Avramenko, Kazunori Nakashima, Chikara Takano, and Satoru Kawasaki

Published

2023

30. Artificial Fusion Protein to Facilitate Calcium Carbonate Mineralization on Insoluble Polysaccharide for Efficient Biocementation

Author

Thiloththama Hiranya Kumari Nawarathna, Tetsuya Kawabe, Kazunori Nakashima, Kiyofumi Kurumisawa, Satoru Kawasaki, and Wilson Mwandira

Subjects

chemistry.chemical_classification, chemistry.chemical_compound, Calcium carbonate, Biochemistry, chemistry, Renewable Energy, Sustainability and the Environment, General Chemical Engineering, Environmental Chemistry, General Chemistry, Mineralization (soil science), recombinant protein, hybrid materials, biopolymer, calcium carbonate, biocementation, Polysaccharide, Fusion protein

Abstract

Biomineralization is a process of mineral formation in living organisms. Compared with nonbiogenic minerals, biominerals can be defined as organic–inorganic hybrid materials that have excellent physical and optical properties. In the current study, an artificial protein mimicking the outer shell of crayfish, composed of CaCO3, chitin, and proteins, was developed to facilitate organic–inorganic hybrid material formation by precipitation of calcium carbonate on the chitin matrix. The fusion protein (CaBP-ChBD) was constructed by introducing a short-sequence calcite-binding peptide (CaBP) into the chitin-binding domain (ChBD). Calcium carbonate precipitation experiments by enzymatic urea hydrolysis revealed that a significant increase in the CaCO3 formation was achieved by adding CaBP-ChBD. Also, CaCO3 was efficiently deposited on chitin particles decorated with CaBP-ChBD. Most interestingly, CaBP-ChBD would improve the performance in sand solidification more efficiently and sustainably in the process of biocementation technique. The developed recombinant protein could be used for the sustainable production of organic–inorganic green materials for engineering applications.

Published

2021

31. Durability analysis of bio-cemented slope soil under the exposure of acid rain

Author

Kazunori Nakashima, Satoru Kawasaki, and Sivakumar Gowthaman

Subjects

Chemistry, Stratigraphy, Cementation level, 0211 other engineering and technologies, Soil science, Long-term performance, 02 engineering and technology, Slope surface, Cementation (geology), Infiltration (HVAC), Durability, Preservation, Corrosion, Compressive strength, 021105 building & construction, Soil water, Microbial-induced carbonate precipitation (MICP), Acid rain, Precipitation, 021101 geological & geomatics engineering, Earth-Surface Processes

Abstract

Purpose Instability of slope surface is a critical concern in Geotechnical and Environmental Engineering. MICP (Microbial-Induced Carbonate Precipitation), an innovative bio-cementation technique, has attracted the attention for slope surface protection. In this work, MICP was investigated to evaluate its durability under the exposure of acid rain and to advance the understanding on long-term performance of slope soil preserved by MICP. Methods MICP treatment was applied to a fine-grained slope soil using indigenous bacteria. Specimens treated to different cementation levels (% CaCO3) were exposed to acid rain (of varying pH) through two sorts of mechanisms: (i) infiltration and (ii) immersion. The evaluations were based on corrosion of CaCO3, mass loss, needle penetration tests, and scanning electron microscopy. Results The decrease in pH increased the corrosion of CaCO3, resulting in considerable loss in aggregate and unconfined compressive strength. However, increased cementation level showed high durability of specimens. The soils treated to 12.5% CaCO3 showed 19.9% soil loss, whereas it was reduced to 5.4% when cemented to 22.5% CaCO3. The results also revealed that the contact time of acid rain significantly governed the rate of corrosion, i.e., specimens subjected to lower infiltration rate (20 mm/h) showed higher loss of mass compared to that of higher rate (100 mm/h). Conclusion The long-term performance of MICP treatment is determined by (i) cementation level, (ii) pH, and (iii) infiltration rate of acid rain. High cementation level promotes the longevity of the treatment. Therefore, MICP to higher cementation level is recommended for long-term preservation of slope surface.

Published

2021

32. Differential diagnosis between calcifying odontogenic cyst and adenomatoid odontogenic tumor by computed tomography images

Author

Takashi Eda, Satsuki Wakae-Morita, Kaoru Kobayashi, Shintaro Okura, Hirokazu Ito, Kazunori Nakashima, Yumi Ito, Masashi Sugisaki, and Chinami Igarashi

Subjects

Male, Radiography, Odontogenic Tumors, Computed tomography, 030218 nuclear medicine & medical imaging, Ameloblastoma, Diagnosis, Differential, Lesion, 03 medical and health sciences, Calcifying odontogenic cyst, 0302 clinical medicine, stomatognathic system, medicine, Humans, Radiology, Nuclear Medicine and imaging, Dentistry (miscellaneous), medicine.diagnostic_test, business.industry, Impacted tooth, Adenomatoid odontogenic tumor, 030206 dentistry, Anatomy, Odontogenic Cyst, Calcifying, medicine.disease, stomatognathic diseases, Odontogenic Cysts, Oral and maxillofacial surgery, Female, medicine.symptom, Differential diagnosis, Tomography, X-Ray Computed, business

Abstract

Calcifying odontogenic cysts (COC) and adenomatoid odontogenic tumors (AOT) have similar radiographic findings. We examined the radiographic and computed tomography (CT) images of patients histologically diagnosed with COC or AOT and identified their characteristic findings. The subjects included 12 patients histologically diagnosed with COC or AOT (one female and five males per group), who underwent CT at our hospital between Nov 1998 and Jun 2019. The location of the lesion, impacted tooth, bone expansion, root resorption, tooth migration, calcified body, and presence or absence of a high-intensity zone in the marginal area of the lesion were examined. In patients with COC, five patients with COC exhibited bone expansion toward the buccal side. The lesion encompassing the crown was attached to the cement-enamel junction and contained a radiopaque lesion with a calcified body. In 6 patients with COC, irregularly shaped calcified bodies were observed with small tooth-like structures. In patients with AOT, all six patients with AOT exhibited bone expansion toward the buccal and lingual sides. The lesion encompasses a part of the tooth root or the entire tooth. Punctate calcification was observed within the lesion and the marginal area in three patients, and a high-intensity zone was observed in the marginal area of the lesion in two patients. We report imaging findings that may be characteristic of COC and AOT, suggesting that CT findings may be useful for differentiating between COC and AOT.

Published

2021

33. Effect of wetting and drying cycles on the durability of bio-cemented soil of expressway slope

Author

Sivakumar Gowthaman, Kazunori Nakashima, and Satoru Kawasaki

Subjects

Environmental Engineering, Materials science, 0211 other engineering and technologies, Weathering, Slope surface, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Durability, chemistry.chemical_compound, Environmental Chemistry, Geotechnical engineering, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Cementation level, Cementation (geology), Stabilization, Wet-dry cycles, chemistry, Soil water, Erosion, Carbonate, Degradation (geology), Wetting, General Agricultural and Biological Sciences, Microbial induced carbonate precipitation

Abstract

Cyclic wet-dry is one of the influential weathering agents which can rapidly alter the mechanical properties of soils, limiting their durability and consistent performance. This study investigates the effect of wet-dry cycles on the mechanical behaviour of bio-cemented soil. Microbial-induced carbonate precipitation-based bio-cementation is an innovative soil improvement method, which is gaining increasing attention as a potential alternative for stabilizing slope surface. As the treated surfaces are exposed to repeated rainfalls and draughts, durability analysis is essential; cyclic wet-dry tests were therefore performed as a credible indicator of durability. The soil obtained from the Hokkaido expressway slope was treated at laboratory to varying cementation levels (% CaCO3) and subjected to 50 subsequent wet-dry cycles. Physical and mechanical changes were monitored using mass loss, shear wave velocities and needle penetration tests during wet-dry cycles. The results showed that the wet-dry cycles deteriorated the physical and mechanical at two stages. The mass and S-wave velocity of specimens significantly dropped after first few cycles and then tended to reach equilibrium. The second stage of notable deterioration was observed between 30 and 50 wet-dry cycles. It is suggested that the erosion of weak and powdery deposition of CaCO3 causes the degradation at the early stage, whereas the degradation in the late stage was attributed to the microstructural deformations of intact carbonate bonds. It was also found that the increase in cementation level decreases the deterioration of bio-cemented soil under wet-dry cycles.

Published

2021

34. Distribution and cementation characteristics of beachrocks along southern, southwestern and western coast of Sri Lanka

Author

Kazunori Nakashima, A. B. N. Dassanayake, Satoru Kawasaki, and Pahala Ge Nishadi Nayanthara

Subjects

Beachrock, Calcite, 010504 meteorology & atmospheric sciences, Beachrocks, Aragonite, Marine phreatic precipitation, Geochemistry, engineering.material, 010502 geochemistry & geophysics, Cementation (geology), Microfabrics and textures, Spectroscopic analysis, 01 natural sciences, Sedimentary structures, Conglomerate, Petrography, chemistry.chemical_compound, chemistry, engineering, Carbonate, Geology, Carbonate cements, 0105 earth and related environmental sciences

Abstract

Beachrocks are sedimentary structures where gravelly or sandy beaches have been transformed into rock outcrops formed through precipitation of connective cements amid their interstices. They are well-noted coastal features along the coastal belt of Sri Lanka due to the prevalent tropical climate. This study was aimed at gathering data on surface nature and cementation characteristics of beachrock occurrences along a part of Sri Lankan shoreline through field observations and a series of analyses including X-ray diffraction, X-ray fluorescence, scanning electron microscopy (SEM) techniques and petrographic thin-section analysis. The combined research findings from different techniques are also employed as a preliminary step to determine the formation mechanism of the studied beachrocks. The seaward-inclined low-angle beds running parallel to present shoreline are composed mostly of sandstone with occasional conglomerate. Almost all the beachrocks are made of quartz grains amalgamated by cement. One remarkable feature of Sri Lankan beachrocks is the presence of heavy minerals generally in thin lamina form. The cementing agents are predominantly composed of metastable carbonate phases, high magnesium calcite (HMC) and aragonite (Ar) with varying microfabrics and textures. From SEM examinations and thin-section images, main morphologies identified are acicular Ar, scalenohedral magnesium calcites along with bridge cements and micritic coatings which are typical of a marine-phreatic precipitation with the exception of occasional meniscus cements. Further, the presence of evidences of living organisms may be an indication of influence from the biological aspects which can be confirmed by more detailed analyses.

Published

2021

35. A two-stage treatment process for the management of produced ammonium by-products in ureolytic bio-cementation process

Author

Satoru Kawasaki, Taghi Ebadi, A. Mohsenzadeh, Kazunori Nakashima, Esmail Aflaki, and Sivakumar Gowthaman

Subjects

Environmental Engineering, Precipitation (chemistry), Chemistry, 010501 environmental sciences, Phosphate, 01 natural sciences, chemistry.chemical_compound, Distilled water, Cementation process, Struvite, Desorption, Environmental Chemistry, Carbonate, Ammonium, General Agricultural and Biological Sciences, 0105 earth and related environmental sciences, Nuclear chemistry

Abstract

Since the last decade, microbial-induced carbonate precipitation has been proposed as an environmentally friendly technique to improve the engineering properties of soil. Despite the considerable progress on ureolytic bio-cementation, one of the major concerns that has not been solved yet is related to the production of ammonium. This study aimed to manage ammonium ions to attain a sustainable pathway for bio-cementation treatment. To this end, a two-stage treatment including rinsing of ammonium from soil combined with a recovery of ammonium was considered herein for the first time. In the rinsing process, the followings were studied to optimize ammonium removal from soil: the effects of pH, concentration, and the single salts of the rinse solution. In the subsequent ammonium recovery process, the effects of phosphate source, pH, molar ratio, and Ca2+ ions were extensively investigated. The results revealed that at neutral pH conditions, ammonium removal was the lowest (68.82%). The MgCl2 solution was found to have the greatest ability to remove ammonium followed by CaCl2, NaCl, and distilled water (98.54%, 96.47%, 89.95%, and 74.77%, respectively). The ammonium recovery results showed that 86.8% of ammonium ions could be recovered as a high purity struvite (~ 94%), and that the optimum recovery was achieved at the following conditions: Na2HPO4 as a phosphate source, the Mg2+: $${\text{NH}}_{4}^{ + }$$ : $${\text{PO}}_{4}^{3 - }$$ molar ratio of 1.2: 1: 1, and a pH of 8.5. Overall, it was demonstrated that the proposed method could be an effective way for sustainable ammonium by-products management.

Published

2021

36. Valorization of tannery solid wastes for sustainable enzyme induced carbonate precipitation process

Author

Parthasarathy Baskaran Sujiritha, Vijan Lal Vikash, George Sebastian Antony, Ganesan Ponesakki, Niraikulam Ayyadurai, Kazunori Nakashima, and Numbi Ramudu Kamini

Subjects

Environmental Engineering, Sewage, Nitrogen, Health, Toxicology and Mutagenesis, Public Health, Environmental and Occupational Health, Oxides, General Medicine, General Chemistry, Calcium Compounds, Solid Waste, Pollution, Urease, Calcium Carbonate, Calcium Chloride, Sand, Environmental Chemistry, Urea, Calcium

Abstract

Biocementation via enzyme induced carbonate precipitation (EICP) is an emerging ground improvement technique that utilizes urease for calcium carbonate precipitation. Usage of expensive laboratory grade chemicals in EICP hinders its implementation at field level applications. In this study, the feasibility of utilizing solid wastes generated from leather industry was investigated for EICP process. Initially, the proteinaceous fleshing waste was used as nitrogen source for production of an extracellular urease from Arthrobacter creatinolyticus MTCC 5604 followed by its subsequent use in EICP with suspended solids of tannery lime liquor, as alternative calcium source. The calcium ion solution was prepared by treating suspended solids of lime liquor with 1 N HCl. The EICP was optimum with 1000 U of urease, 1.0 M urea and 1.0 M CaCl

Published

2022

37. Freeze-thaw durability and shear responses of cemented slope soil treated by microbial induced carbonate precipitation

Author

Sivakumar Gowthaman, Satoru Kawasaki, and Kazunori Nakashima

Subjects

021110 strategic, defence & security studies, Materials science, Slope soil, Shear response, Cementation level, 0211 other engineering and technologies, 02 engineering and technology, Geotechnical Engineering and Engineering Geology, Cementation (geology), Durability, Residual strength, Freeze-thaw response, Pore water pressure, Soil stabilization, Soil water, Cohesion (geology), Geotechnical engineering, Direct shear test, 021101 geological & geomatics engineering, Civil and Structural Engineering

Abstract

Instability of slope soils under varying nature is one of the serious concerns in geotechnical engineering. Microbial induced carbonate precipitation (MICP) is a recently emerged, biological ground improvement technique, and that has the potential to enhance the shear strength, modify the surface conditions and promote the stability of deposits. This paper presents the experimental works conducted to investigate the durability and shear responses of MICP treated slope soil, demonstrating the feasibility of technique as potential alternative for slope soil stabilization. The first objective is to investigate the freeze–thaw (FT) response of MICP specimens, because FT cycles can affect the aggregate stability in regions with seasonal frost, which in turn impacts runoff and erosion in slopes. FT tests were performed as a credible indicator of durability, and the subjected specimens were monitored nondestructively (mass loss, S-wave, P-wave velocities). Secondly, shear tests were performed, and effective strength properties were analyzed at peak and residual states. FT test results suggest that contact cementation provides additional resistive forces in slope soil against progressive expansion of pore water during FT; however, aggregate stability is attributed to adequate cementation level which facilitates effective particle contacts. Shear test results indicate that MICP has influence on friction and cohesion parameters. However, the residual strength is mainly contributed by friction angle, only a minor effect from cohesion.

Published

2020

38. Biological Route to Fabricate Silica on Cellulose Using Immobilized Silicatein Fused with a Carbohydrate-Binding Module

Author

Kazunori Nakashima, Satoru Kawasaki, Kasun Godigamuwa, and Junnosuke Okamoto

Subjects

Polymers and Plastics, Bioengineering, 02 engineering and technology, Protein tag, 010402 general chemistry, 01 natural sciences, Catalysis, Biomaterials, chemistry.chemical_compound, Materials Chemistry, Cellulose, chemistry.chemical_classification, Biomolecule, Substrate (chemistry), Silicon Dioxide, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Tetraethyl orthosilicate, chemistry, Chemical engineering, Biocatalysis, Microscopy, Electron, Scanning, Carbohydrate-binding module, 0210 nano-technology, Hybrid material, Biosensor

Abstract

Silicatein is an enzyme capable of catalyzing silica formation under mild conditions and is a promising catalyst for the fabrication of biohybrid materials. However, unfavorable aggregation of silicatein makes it unsuitable for use in material fabrication. In this study, a soluble protein tag (ProS2) and a carbohydrate-binding module (CBM) were used to develop a soluble and cellulose-binding fusion silicatein, ProS2-Sil-CBM, which can be efficiently immobilized on cellulose to form silica on it. ProS2-Sil-CBM was soluble in aqueous media and strongly bound to cellulose. ProS2-Sil-CBM bound on cellulose catalyzed the formation of a silica layer on the cellulose in the presence of tetraethyl orthosilicate as the substrate. Scanning electron microscopy (SEM) and surface elemental analysis confirmed the formation of silica on cellulose. This technique can be used to fabricate inorganic-organic hybrid materials to immobilize biomolecules and can be applied to develop novel biocatalytic systems, biosensors, and tissue culture scaffolds.

Published

2020

39. Microbial Leaching of Iron from Hematite: Direct or Indirect Elution

Author

Apichaya Aneksampant, Kazunori Nakashima, and Satoru Kawasaki

Subjects

Materials science, Mechanics of Materials, Elution, Mechanical Engineering, Environmental chemistry, visual_art, visual_art.visual_art_medium, General Materials Science, Leaching (metallurgy), Hematite, Condensed Matter Physics

Published

2020

40. List of contributors

Author

Daniel J. Bailey, Mostafa Benzaazoua, Bauyrzhan Biakhmetov, Bora Cetin, Laurent Charlet, Vincent Chatain, Jing Chen, Liang Chen, Meiqi Chen, Julien Couvidat, Louise Darricau, Sabino De Gisi, Abay Dostiyarov, Yan-Jun Du, Yassine El Khessaimi, Abdellatif Elghali, Zhuoting Fang, Alejandro Fernandez-Martinez, Laura J. Gardner, Daniel A. Geddes, Sivakumar Gowthaman, Binglin Guo, Rachid Hakkou, Theodore Hanein, Niklas Hedin, Md. Uzzal Hossain, Qing Hu, Jizhi Huang, Neil C. Hyatt, Ning-Jun Jiang, Fei Jin, Marouen Jouini, Satoru Kawasaki, Sarah Kearney, Shin Komatsu, Claudia Labianca, Jiangshan Li, Wengui Li, Tung-Chai Ling, Yue Liu, Alexander Lyubartsev, Bin Ma, Zengyi Ma, Zhiming Ma, Safaa Mabroum, Masrur Mahedi, Kim Hung Mo, Wilson Mwandira, Kazunori Nakashima, Carmen Mihaela Neculita, Shaun Nelson, S. Thomas Ng, Michele Notarnicola, Phuong Ngoc Pham, Chi-Sun Poon, John L. Provis, Yutong Qi, Yuandong Qian, Pengfei Ren, Shaoqin Ruan, Keiko Sasaki, Zhengtao Shen, Shi-Kuan Sun, Yassine Taha, Shengheng Tan, Pei Tang, Zhuo Tang, Quanzhi Tian, Francesco Todaro, Lizhi Tong, Daniel C.W. Tsang, Brant Walkley, Fei Wang, Lei Wang, Linling Wang, Xin Wang, Jianzhuang Xiao, Xinni Xiong, Weiting Xu, Jianhua Yan, Jinqin Yang, Antonia S. Yorkshire, Siming You, Yike Zhang, Yunhui Zhang, Yuying Zhang, Nannan Zhao, Pucheng Zhong, Yifan Zhou, and Yan Zhuge

Published

2022

41. Organic-Inorganic Hybrid Green Materials for Soil Improvement

Author

Thiloththama Hiranya Kumari Nawarathna, Sivakumar Gowthaman, Kazunori Nakashima, and Satoru Kawasaki

Published

2022

42. Biocementation technology for stabilization/solidification of organic peat

Author

Sivakumar Gowthaman, Meiqi Chen, Kazunori Nakashima, Shin Komatsu, and Satoru Kawasaki

Published

2022

43. A Novel Metal Adsorbent Composed of a Hexa-histidine Tag and a Carbohydrate-binding Module on Cellulose

Author

Kazunori Nakashima, Satoru Kawasaki, Wilson Mwandira, and Yuki Togo

Subjects

Surface Properties, Carbohydrates, 02 engineering and technology, metal affinity tag, 01 natural sciences, transition metals, Analytical Chemistry, Metal, chemistry.chemical_compound, Adsorption, Transition metal, Nickel, Polymer chemistry, Histidine, Particle Size, Cellulose, Carbohydrate-binding module, Binding Sites, Chemistry, 010401 analytical chemistry, Proteins, 021001 nanoscience & nanotechnology, HEXA, 0104 chemical sciences, visual_art, immobilization, visual_art.visual_art_medium, HSAB theory, 0210 nano-technology

Abstract

We developed a novel metal adsorbent composed of bio-based materials, cellulose and a protein. The approach involved the immobilization of a hexa-histidine tag (His(6)), which shows an affinity for an intermediate acid (metal ion) in Hard and Soft Acids and Bases (HSAB) theory, on cellulose by fusing with a carbohydrate-binding module (CBM). The results show that CBM-His(6)-bound cellulose has adsorption selectivity reflecting the original properties of His(6). Additionally, we prepared three configurations of CBM-His(6) proteins, which were subsequently immobilized on filter paper for Ni2+ ion adsorption. Of these configurations, we found that the protein containing two His(6) tags at each terminus (N- and C-) of CBM exhibited the highest metal adsorption ability. Furthermore, XPS analysis confirmed the binding of Ni2+ ions on the cellulose.

Published

2019

44. Experimental Study on Sand Stabilization Using Bio-Cementation with Wastepaper Fiber Integration

Author

Kazunori Nakashima, Shin Komatsu, Sivakumar Gowthaman, Satoru Kawasaki, and Meiqi Chen

Subjects

Technology, Materials science, mechanical properties, Article, chemistry.chemical_compound, microbially-induced carbonate precipitation (MICP), freeze-thaw durability, General Materials Science, calcium carbonate, Fiber, Composite material, Ductility, Microscale chemistry, Microscopy, QC120-168.85, Precipitation (chemistry), QH201-278.5, Cementation (geology), Engineering (General). Civil engineering (General), Durability, TK1-9971, wastepaper fiber, Calcium carbonate, chemistry, Descriptive and experimental mechanics, Particle, Electrical engineering. Electronics. Nuclear engineering, TA1-2040

Abstract

Recently, green materials and technologies have received considerable attention in geotechnical engineering. One of such techniques is microbially-induced carbonate precipitation (MICP). In the MICP process, CaCO3 is achieved bio-chemically within the soil, thus enhancing the strength and stiffness. The purpose of this study is to introduce the wastepaper fiber (WPF) onto the MICP (i) to study the mechanical properties of MICP-treated sand with varying WPF content (0–8%) and (ii) to assess the freeze–thaw (FT) durability of the treated samples. Findings revealed that the ductility of the treated samples increases with the increase in WPF addition, while the highest UCS is found with a small fiber addition. The results of CaCO3 content suggest that the WPF addition enhances the immobilization of the bacteria cells, thus yielding the precipitation content. However, shear wave velocity analysis indicates that a higher addition of WPF results in rapid deterioration of the samples when subjected to freeze–thaw cycles. Microscale analysis illuminates that fiber clusters replace the solid bonding at particle contacts, leading to reduced resistance to freeze–thaw damage. Overall, the study demonstrates that as a waste material, WPF could be sustainably reused in the bio-cementation.

Published

2021

45. SOIL IMPROVEMENT USING CALCIUM PHOSPHATE COMPOUNDS AS A NOVEL SUSTAINABLE METHOD: A REVIEW.

Author

Maksym Avramenko, Kazunori Nakashima, Chikara Takano, and Satoru Kawasaki

Subjects

CALCIUM compounds, CALCIUM phosphate, PRECIPITATION (Chemistry), SOILS, SOIL stabilization, CALCIUM ions, UREASE

Abstract

Many new soil reinforcement techniques have recently emerged, the most popular of which are microbial-induced carbonate precipitation (MICP) and enzyme-induced carbonate precipitation (EICP). They are environmentally friendly and more sustainable than conventional methods for soil stabilization, however during carbonate (e.g., calcite) precipitation, ammonia (NH3) and ammonium (NH4+) emissions are released into air and groundwater, which are hazardous. There are techniques for removing NH4+ from the soil, however, the ammonia problem remains to be addressed. By using calcium phosphate compounds (CPCs), ammonium emissions can be eliminated by more than 90%. The precipitation of calcium phosphate occurs when the calcium and phosphorus sources interact at increasing pH of the medium. Deposition type of CPCs depends on pH of environment and Ca/P ratio of solution. The most common precipitation methods are: 1) mixing calcium and phosphorus sources directly; and 2) mixing urea and acid urease or acidic bacteria with Ca and P sources. Deposition takes place in between sand particles enhancing their contact and, therefore, strengthens the soil. Given the relatively low popularity and lack of research on CPCs for soil improvement, this review discusses soil improvement methods using CPCs, their prospects, and their limitations. In addition, it will also show differences in products when using different methods of obtaining CPCs and merits of using CPCs. [ABSTRACT FROM AUTHOR]

Published

2023

46. Solidification of sand by Pb(II)-tolerant bacteria for capping mine waste to control metallic dust: Case of the abandoned Kabwe Mine, Zambia

Author

Satoru Kawasaki, Hokuto Nakata, Toshifumi Igarashi, Shouta M.M. Nakayama, Tsutomu Sato, Wilson Mwandira, Mayumi Ito, Meki Chirwa, Kazunori Nakashima, Imasiku Nyambe, Kawawa Banda, and Mayumi Ishizuka

Subjects

Environmental Engineering, Health, Toxicology and Mutagenesis, 0208 environmental biotechnology, Zambia, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Mining, Calcium Carbonate, Rainwater harvesting, Metal, Bioremediation, Hazardous waste, Chemical Precipitation, Environmental Chemistry, Cementation, 0105 earth and related environmental sciences, Pollutant, Bacteria, Public Health, Environmental and Occupational Health, Environmental engineering, Dust, Heavy metals, General Medicine, General Chemistry, Contamination, Silicon Dioxide, Pollution, 020801 environmental engineering, Kabwe, Mine waste, Capping Indigenous ureolytic bacteria, Biocementation, Biodegradation, Environmental, Lead, visual_art, visual_art.visual_art_medium, Environmental science, Leaching (metallurgy)

Abstract

Environmental impacts resulting from historic lead and zinc mining in Kabwe, Zambia affect human health due to the dust generated from the mine waste that contains lead, a known hazardous pollutant. We employed microbially induced calcium carbonate precipitation (MICP), an alternative capping method, to prevent dust generation and reduce the mobility of contaminants. Pb-resistant Oceanobacillus profundus KBZ 1–3 and O. profundus KBZ 2–5 isolated from Kabwe were used to biocement the sand that would act as a cover to prevent dust and water infiltration. Sand biocemented by KBZ 1–3 and KBZ 2–5 had maximum unconfined compressive strength values of 3.2 MPa and 5.5 MPa, respectively. Additionally, biocemented sand exhibited reduced water permeability values of 9.6 × 10−8 m/s and 8.9 × 10−8 m/s for O. profundus KBZ 1–3 and KBZ 2–5, respectively, which could potentially limit the entrance of water and oxygen into the dump, hence reducing the leaching of heavy metals. We propose that these isolates represent an option for bioremediating contaminated waste by preventing both metallic dust from becoming airborne and rainwater from infiltrating into the waste. O. profundus KBZ 1–3 and O. profundus KBZ 2–5 isolated form Kabwe represent a novel species that has, for the first time, been applied in a bioremediation study.

Published

2019

47. Chitosan enhances calcium carbonate precipitation and solidification mediated by bacteria

Author

Kazunori Nakashima, Satoru Kawasaki, and Thiloththama Hiranya Kumari Nawarathna

Subjects

Nucleation, macromolecular substances, 02 engineering and technology, Polysaccharide, Biochemistry, Calcium Carbonate, Chitosan, 03 medical and health sciences, chemistry.chemical_compound, Hydrolysis, Structural Biology, Chemical Precipitation, Urea, Rhodobacteraceae, Molecular Biology, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Precipitation (chemistry), technology, industry, and agriculture, General Medicine, equipment and supplies, 021001 nanoscience & nanotechnology, carbohydrates (lipids), Calcium carbonate, chemistry, Chemical engineering, Carbonate, 0210 nano-technology, Biomineralization

Abstract

Formation of the biominerals in living organisms is mainly associated with organic macromolecules. These organic materials play an important role in the nucleation, growth, and morphology controls of the biominerals. Current study mimics this concept of organic matrix- mediated biomineralization by using microbial induced carbonate precipitation (MICP) method in combination with the cationic polysaccharide chitosan. CaCO3 precipitation was performed by the hydrolysis of urea by the ureolytic bacteria Pararhodobacter sp. SO1 in the presence of CaCl2, with and without chitosan. The crystal polymorphism and morphology of oven-dried samples were analyzed by X-ray diffraction and scanning electron microscopy. The amount of precipitate obtained was higher in the presence of chitosan. The precipitate included both of the CaCO3 and the chitosan hydrogel. Rhombohedral crystals were dominant in the precipitate without chitosan and distorted crystal agglomerations were found with chitosan. Sand solidification experiments were conducted in the presence of chitosan under different experimental conditions. By adding chitosan, more strongly cemented sand specimens could be obtained than those from conventional method. All of these results confirm the positive effect of chitosan for the CaCO3 precipitation and sand solidification.

Published

2019

48. Efficacy of biocementation of lead mine waste from the Kabwe Mine site evaluated using Pararhodobacter sp

Author

Wilson Mwandira, Tsutomu Sato, Kawawa Banda, Satoru Kawasaki, Shouta M.M. Nakayama, Mayumi Ishizuka, Mayumi Ito, Kazunori Nakashima, Imasiku Nyambe, Meki Chirwa, and Toshifumi Igarashi

Subjects

Hazardous Waste, Water transport, Plant residue, Health, Toxicology and Mutagenesis, General Medicine, 010501 environmental sciences, Contamination, 01 natural sciences, Pollution, Soil contamination, Mine site, Lead, Pararhodobacter, Hazardous waste, Environmental chemistry, Soil Pollutants, Environmental Chemistry, Environmental science, Leachate, 0105 earth and related environmental sciences

Abstract

Biocementation of hazardous waste is used in reducing the mobility of contaminants, but studies on evaluating its efficacy have not been well documented. Therefore, to evaluate the efficacy of this method, physicochemical factors affecting stabilized hazardous products of in situ microbially induced calcium carbonate precipitation (MICP) were determined. The strength and leach resistance were investigated using the bacterium Pararhodobacter sp. Pb-contaminated kiln slag (KS) and leach plant residue (LPR) collected from Kabwe, Zambia, were investigated. Biocemented KS and KS/LPR had leachate Pb concentrations below the detection limit of

Published

2019

49. Biogeotechnical approach for slope soil stabilization using locally isolated bacteria and inexpensive low-grade chemicals: A feasibility study on Hokkaido expressway soil, Japan

Author

Kazunori Nakashima, Masahiro Komatsu, Satoru Kawasaki, Sivakumar Gowthaman, and Shumpei Mitsuyama

Subjects

0211 other engineering and technologies, 02 engineering and technology, Soil surface, chemistry.chemical_compound, Slope soil stabilization, Soil stabilization, Microbial induced calcite precipitation, Low-grade chemicals, 021101 geological & geomatics engineering, Civil and Structural Engineering, Indigenous bacteria, Calcite, 021110 strategic, defence & security studies, biology, Pure chemicals, Environmental engineering, Geotechnical Engineering and Engineering Geology, biology.organism_classification, Cementation (geology), Compressive strength, chemistry, Environmental science, Carbonate, Bacteria

Abstract

Microbial Induced Calcite Precipitation (MICP) is one of the most popular biotechnological soil stabilization techniques since it results in significant improvements in the geotechnical properties of soil. The current study presents a laboratory-scale MICP investigation performed to demonstrate the feasibility of slope soil stabilization of the Hokkaido expressway through surficial treatment. The objectives of this preliminary study are to investigate the feasibility of (i) augmenting indigenous bacteria, and (ii) implementing commercially available inexpensive low-grade chemicals in microbial induced solidifications. Syringe solidification tests were carried out using indigenous ureolytic bacteria under various temperature condition with the use of different injection sources. A high strength crust layer was achieved on the soil surface with 420 kPa unconfined compressive strength (UCS) as measured by needle penetration test after 10 days of treatment using pure chemicals (30 degrees C; 0.5 M cementation solution, every 24 h; bacterial culture solution, only at the beginning). However, by substituting pure chemicals with low-grade chemicals, a significant improvement in the UCS of soil (820 kPa at 30 degrees C) was obtained together with a 96% reduction in the treatment cost. The morphologies and crystalline structures of the precipitated carbonate were characterized by Scanning Electron Microscopical (SEM) observations. This alternative approach of introducing low-grade chemicals in MICP has the potential to provide significant economic benefits in field-scale applications.

Published

2019

50. IMPROVEMENT OF USING CRUDE EXTRACT UREASE FROM WATERMELON SEEDS FOR BIOCEMENTATION TECHNOLOGY

Author

Kazunori Nakashima, Satoru Kawasaki, Al Imran, and Niki Evelpidou

Subjects

Calcite, Environmental Engineering, Citrullus lanatus, biology, Urease, Aragonite, Soil Science, Liquefaction, Building and Construction, engineering.material, Geotechnical Engineering and Engineering Geology, biology.organism_classification, Pulp and paper industry, chemistry.chemical_compound, chemistry, Vaterite, engineering, Urea, biology.protein, Carbonate

Abstract

In recent years,the formation of artificial beachrock and bio-cementation method has gained considerable attention as a sustainable alternative tool in the area of geotechnical and geo-environmental engineering field for soil improvement and construction materials. In general, earlier methods of soil improvement were mostly concentrated on microbes (Bacteria, Fungi, etc.) as a source of urease enzyme widely known as MICP method (Microbial Induced Carbonate Precipitation). To address some of the keylimitations of MICP method this study focused on using crude enzyme (low cost, eco-friendly). Crude enzyme was extracted from watermelon seeds (Citrullus lanatus)considered as “food waste material” and the carbonate formation process known as EICP “Enzyme Induced Carbonate Precipitation.” Crushed and blended watermelon seeds (both dry and germinated) used as a source of urease enzyme. Subsequently, their urease activity was also investigated with various environmental parameters (Temperature, pH, etc.) and investigated the carbonate precipitation trend using calcium chloride (CaCl2) and urea [(CO(NH2)2]. The form of carbonate (calcite, aragonite, vaterite, etc.) was also confirmed by XRD and SEM-EDX analysis. Finally, syringe (d = 2.3 cm, h = 7.1 cm) sand solidification test was conducted using commercially available “Mikawa sand” (mean diameter, D50 = 870 mm) and successfully achieved unconfined compressive strength (UCS) of about 1.2 MPa at neutral pH (~7) and temperature condition (30 °C) considering various curing days and conditions. This study could be useful as an eco-friendly and sustainable method for numerous bio-geotechnical applications (for instance, ground improvement, liquefaction mitigation, artificial beach rock formations, coastal erosion protection, etc.) and the extracted crude urease from watermelon seeds could play as an alternative to replace commercially available urease for carbonate precipitation.

Published

2021