CAREER: Microstructural Characterization and Modeling of Geomaterials
职业:岩土材料的微观结构表征和建模
基本信息
- 批准号:0134519
- 负责人:
- 金额:--
- 依托单位:
- 依托单位国家:美国
- 项目类别:Standard Grant
- 财政年份:2002
- 资助国家:美国
- 起止时间:2002-08-15 至 2003-05-31
- 项目状态:已结题
- 来源:
- 关键词:
项目摘要
Microstructure characterization and modeling are essential for the understanding of the macroscopic behavior of engineering materials. It is often used to design new materials with tailored microstructures, obtain parameters for multiscale continuum models, and simulate engineering processes at the material microstructure level. Microstructure characterization techniques have significantly advanced the understanding of many engineering materials such as metals, ceramics, and composites.This Faculty Early Career Development (CAREER) research and education project offers a novel approach for linking the geomaterials microstructure to their macroscopic properties. It focuses on developing an approach to quantify the three-dimensional geomaterial microstructure and its influence on fluid flow characteristics and directional permeability. These properties have significant impact on several phenomena in geomaterials such as the stability of saturated soils, contaminant transport in soils, oil transport in rocks, and the performance of pavements. The proposed research is well balanced between experimental methods for characterizing the 3-D microstructure of geomaterials, numerical modeling, and computer simulation. X-ray computed tomography (CT) will be used to capture the three-dimensional microstructure of geomaterials. Computational fluid dynamics will be used to develop a numerical solution to the fluid flow equations within the boundary conditions of the material microstructure as defined by the X-ray CT images. Experimental measurements will be used to verify the developed models and computer simulations. The outcome of this research will provide unique insight into the influence of the microstructure on the macroscopic properties of geomaterials. It will offer a fundamental approach for predicting material permeability and fluid flow characteristics that will ultimately lead to effective design of geosystems.These research activities will be integrated in an educational program that incorporates recent advances in experimental non-destructive techniques, image analysis, numerical modeling, and computer simulation into the academic curriculum through team-oriented projects conducted by undergraduate students, and graduate course development. A summer educational program will also be established that focuses on the participation of high school students, and those recruited from other universities with emphasis on underrepresented groups in engineering. Students will be able to link the microstructure properties to the macroscopic response, and visualize the influence of the microstructure on the material behavior through computer simulations.The project includes a management plan to ensure achieving the research, educational and outreach objectives. It involves an advisory committee consisting of multidisciplinary individuals from academia, research institutions, and government agencies. The role of this committee will be to offer technical advice, facilitate dissemination of the results and ensure exposure of the findings to educational and professional organizations. An additional role of this committee will be to facilitate the involvement of underrepresented student groups.
微观结构表征和建模对于理解工程材料的宏观行为至关重要。它通常用于设计具有定制微结构的新材料,获得多尺度连续体模型的参数,以及在材料微结构水平上模拟工程过程。微观结构表征技术极大地促进了对许多工程材料如金属、陶瓷和复合材料的理解。该学院早期职业发展(Career)研究和教育项目为将岩土材料的微观结构与其宏观特性联系起来提供了一种新颖的方法。重点发展了一种量化三维岩土微观结构及其对流体流动特性和定向渗透率影响的方法。这些特性对饱和土的稳定性、土壤中污染物的运移、岩石中石油的运移以及路面的性能等岩土材料中的几种现象都有重要的影响。所提出的研究在表征岩土材料三维微观结构的实验方法、数值模拟和计算机模拟之间取得了很好的平衡。x射线计算机断层扫描(CT)将用于捕获岩土材料的三维微观结构。计算流体动力学将用于在x射线CT图像定义的材料微观结构的边界条件下开发流体流动方程的数值解。实验测量将用于验证开发的模型和计算机模拟。本研究结果将为岩土材料微观结构对宏观性能的影响提供独特的见解。它将为预测材料渗透率和流体流动特性提供一种基本方法,最终将导致有效的地质系统设计。这些研究活动将整合到一个教育计划中,该计划通过本科生和研究生进行的团队导向项目,将实验无损技术、图像分析、数值模拟和计算机模拟的最新进展纳入学术课程。此外,还将设立一个夏季教育项目,重点是高中生的参与,以及从其他大学招募的学生,重点是工程领域代表性不足的群体。学生将能够将微观结构特性与宏观响应联系起来,并通过计算机模拟可视化微观结构对材料行为的影响。该项目包括一项管理计划,以确保实现研究、教育和推广目标。它包括一个由来自学术界、研究机构和政府机构的多学科人士组成的咨询委员会。该委员会的作用将是提供技术咨询,促进结果的传播,并确保将调查结果提供给教育和专业组织。该委员会的另一个作用是促进代表性不足的学生群体的参与。
项目成果
期刊论文数量(0)
专著数量(0)
科研奖励数量(0)
会议论文数量(0)
专利数量(0)
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Eyad Masad其他文献
Additive manufacturing of polyethylene-based composites sourced from industrial waste
- DOI:
10.1016/j.cirp.2024.03.012 - 发表时间:
2024-01-01 - 期刊:
- 影响因子:
- 作者:
Ayman Karaki;Apostolos Argyros;Vasileios Stratiotou-Efstratiadis;Marwan Khraisheh;Eyad Masad;Nikolaos Michailidis - 通讯作者:
Nikolaos Michailidis
Chemical and multi-scale material properties of recycled and blended asphalt binders
- DOI:
10.1016/j.conbuildmat.2020.119689 - 发表时间:
2020-11-20 - 期刊:
- 影响因子:
- 作者:
K. Lakshmi Roja;Eyad Masad;Bhaskar Vajipeyajula;Wubulikasimu Yiming;Eisha Khalid;Vasanth C. Shunmugasamy - 通讯作者:
Vasanth C. Shunmugasamy
Development of Ca(OH)sub2/sub-based geopolymer for additive manufacturing using construction wastes and nanomaterials
使用建筑废料和纳米材料开发用于增材制造的氢氧化钙基地质聚合物
- DOI:
10.1016/j.cscm.2023.e02258 - 发表时间:
2023-12-01 - 期刊:
- 影响因子:6.600
- 作者:
Youssef Mortada;Eyad Masad;Reginald B. Kogbara;Bilal Mansoor;Thomas Seers;Ahmad Hammoud;Ayman Karaki - 通讯作者:
Ayman Karaki
Effects of nanomodifiers on rheological, chemical, and microstructural properties of asphalt mastics
纳米改性剂对沥青胶浆流变、化学及微观结构性能的影响
- DOI:
10.1016/j.rineng.2025.105750 - 发表时间:
2025-09-01 - 期刊:
- 影响因子:7.900
- 作者:
Sandra Matarneh;Nawal Louzi;Ibrahim Asi;Mu'tasim Abdel-Jaber;Eyad Masad - 通讯作者:
Eyad Masad
A review on material extrusion (MEX) of polyethylene - Challenges, opportunities, and future prospects
聚乙烯材料挤出(MEX)综述——挑战、机遇与未来前景
- DOI:
10.1016/j.polymer.2024.127333 - 发表时间:
2024-07-24 - 期刊:
- 影响因子:4.500
- 作者:
Ayman Karaki;Ahmad Hammoud;Eyad Masad;Marwan Khraisheh;Ahmed Abdala;Mabrouk Ouederni - 通讯作者:
Mabrouk Ouederni
Eyad Masad的其他文献
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{{ truncateString('Eyad Masad', 18)}}的其他基金
CAREER: Microstructural Characterization and Modeling of Geomaterials
职业:岩土材料的微观结构表征和建模
- 批准号:
0315564 - 财政年份:2003
- 资助金额:
-- - 项目类别:
Standard Grant
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