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Collaborative Research: Implementation Strategies and Performance of Unsaturated Bio-Cemented Dune Sand

合作研究：不饱和生物水泥沙丘砂的实施策略和性能

基本信息

批准号：
1933350
负责人：
Brina Montoya
金额：
$ 17.5万
依托单位：
North Carolina State University
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2019
资助国家：
美国
起止时间：
2019-08-15 至 2023-07-31
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=1933350&HistoricalAwards=false
关键词：
Collaborative Research Implementation Strategies Performance

项目摘要

This research will explore a novel approach for dune protection using bio-cementation to stabilize and enhance natural protective structures. Dunes often present the first line of defense for the built environment during extreme wave surge and storm events. In order to remain effective, dunes must resist erosion in the face of these incidents. Understanding the physics of dune erosion is critical for devising ways to mitigate it. The research team will explore multiple treatment implementation techniques and assess their performance under extreme conditions at field-scale in a large wave flume (LWF) at Oregon State University. Dunes will be constructed in the LWF, bio-cemented in-place, and subjected to a series of wave inundations so that their performance may be observed and quantified. The large-scale work will be supported by coupled laboratory and numerical investigations. The numerical investigation will provide insight into the loading conditions for which each treatment implementation alternative is preferred and the treatment design (e.g., required treatment dimensions) to have minimal impact on the natural environment while still providing the required engineering performance. The resulting outcome of this work will provide guidance for enhancing coastal dunes with bio-cementation to prevent damage to infrastructure during extreme events.Bio-cementation may be a viable method to mitigate dune erosion, which in turn would protect coastal infrastructure during extreme events. We will explore two approaches to implement bio-cementation. The first implementation technique will induce bio-cementation at depth within the dune; this will result in an uncemented surficial layer which may erode but will also minimally impact the coastal habitat. The second approach will be geared towards rapid deployment, for example, in preparation for a forecasted storm event anticipated to hit vulnerable dunes. This rapid approach will be sprayed onto the dunes, instead of injected, since this quick application is more likely to be implemented in a rapid deployment. Furthermore, two methods to induce bio-cementation will be explored: microbial induced carbonate precipitation (MICP) and enzyme induced carbonate precipitation (EICP). The EICP implementation will be conducted by the NSF Engineering Research Center for Bio-mediated and Bio-inspired Geotechnics (CBBG). The research approach will include near prototype-scale experiments in the NHERI Hinsdale Wave Research Laboratory (HWRL); this is made possible by collaborating with an existing NSF project, Physics of Dune Erosion During Extreme Surge and Wave Events, which includes placing nearly 1000 tons of sand in the HWRL Large Wave Flume (LWF), the largest of its type in North America and in the top 10 in the world. In addition to the experiments in the LWF, a complementary laboratory testing and integrated numerical modeling program are planned to assess the effects of implementation strategies with overall dune performance. This research will advance bio-cementation technology by providing well-controlled and instrumented case studies to quantitatively compare the effect of implementation techniques on the performance of dunes. The resulting cementation patterns from the two treatment approaches are expected to be different; however, the performance of the two treatment approaches is unknown. This approach will not only develop prototype-scale case studies of two different treatment implementations, but also provide case studies of bio-cemented sand dunes subjected to extreme storm loading conditions. The numerical simulation approach will provide a framework to design and evaluate the stability of the bio-cementation under extreme wave loading.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

这项研究将探索一种新的方法，沙丘保护利用生物胶结，以稳定和加强自然保护结构。沙丘通常是建筑环境在极端波浪和风暴事件中的第一道防线。为了保持有效，沙丘必须在这些事件面前抵抗侵蚀。了解沙丘侵蚀的物理特性对于设计减轻沙丘侵蚀的方法至关重要。研究小组将在俄勒冈州州立大学的大型波浪水槽（LWF）中探索多种处理实施技术，并评估其在极端条件下的性能。沙丘将在LWF中建造，生物胶结到位，并经受一系列波浪淹没，以便观察和量化其性能。大规模的工作将得到耦合实验室和数值研究的支持。数值研究将提供对每个处理实施方案优选的负载条件和处理设计（例如，所需的处理尺寸），以对自然环境具有最小的影响，同时仍然提供所需的工程性能。这项工作的结果将为通过生物胶结增强沿海沙丘提供指导，以防止在极端事件期间对基础设施造成损害。生物胶结可能是减轻沙丘侵蚀的可行方法，这反过来又会在极端事件期间保护沿海基础设施。我们将探讨两种方法来实现生物胶结。第一种实施技术将在沙丘深处引起生物胶结;这将产生一个未胶结的表层，可能会侵蚀，但也会尽量减少对沿海生境的影响。第二种方法将着眼于快速部署，例如，为预计袭击脆弱沙丘的预报风暴做准备。这种快速方法将喷洒到沙丘上，而不是注入，因为这种快速应用更有可能在快速部署中实施。此外，还将探讨两种诱导生物胶结的方法：微生物诱导碳酸盐沉淀（MICP）和酶诱导碳酸盐沉淀（EICP）。EICP的实施将由NSF生物介导和生物启发岩土工程研究中心（CBBG）进行。该研究方法将包括在NHERI欣斯代尔波浪研究实验室（HWRL）进行近原型规模的实验;这是通过与现有的NSF项目合作实现的，该项目是极端浪涌和波浪事件期间沙丘侵蚀的物理学，其中包括在HWRL大浪水槽（LWF）中放置近1000吨沙子，这是北美最大的，也是世界前10名。除了在LWF的实验，一个补充的实验室测试和综合数值模拟程序计划，以评估实施战略的整体沙丘性能的影响。这项研究将通过提供良好的控制和仪器化的案例研究来定量比较实施技术对沙丘性能的影响，从而推进生物胶结技术。预计两种治疗方法产生的骨水泥模式不同;然而，两种治疗方法的性能尚不清楚。这种方法不仅将开发两种不同的治疗实施的原型规模的案例研究，但也提供了极端风暴负荷条件下的生物胶结沙丘的案例研究。数值模拟方法将为设计和评估极端波浪载荷下生物胶结的稳定性提供一个框架。该奖项反映了NSF的法定使命，并通过使用基金会的知识价值和更广泛的影响审查标准进行评估，被认为值得支持。