Deep sea microfluidic sensors

深海微流体传感器

• 批准号: RGPIN-2019-03999
• 负责人: Sieben, Vincent
• 金额: $ 2.04万
• 依托单位: Dalhousie University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=682213
• 关键词: Deep; sea; microfluidic; sensors

The ocean, like many aquatic environments, is presently under-sampled both spatially (3D) and temporally (+1D) due to current approaches to data gathering. The current practice of sending manned missions to sea will not scale very well if we are to observe, characterize and intervene on important problems in the ocean. Unmanned water vehicles, or marine drones, offer the ability to perform remote sampling and characterization in 4D for both a) rapid response and b) large-scale persistent networks. However, equipping these marine vehicles with biogeochemical sensing capabilities is challenging since commercially available sensors are: 1) too large, 2) too expensive and 3) too energy demanding. A step-change in sensing approach is required to provide ocean chemistry and microbiology data from global observation networks.******In this proposal, the utilization of microfluidic systems and lab-on-a-chip (LOC) devices will be explored for transforming current practices in acquiring ocean biogeochemical observations. Inexpensive and versatile LOC sensors will allow us to quickly, effectively, and accurately monitor ocean biogeochemistry over a wide range of deployment scenarios and across an array of locations. These microfabricated systems combine a wide-range of technologies and often integrate optics, flow control, and electronics. Microfluidic platforms naturally lend themselves toward lower reagent and power consumption, as well as reduced physical size. However, most microfluidic systems are designed for standard pressure and temperature ranges. Very few lab-on-chip systems have been designed with the intention of deployment in the deep ocean. ******The focus of this research program will be on creating the key microfabricated components to permit deep-ocean deployment of LOC devices. These horizontal enablers will permit several biogeochemical measurements and will unlock a scalable strategy for remote monitoring of the ocean interior. Specific outcomes will include: 1) nutrient analyzers for monitoring anthropogenic activities that have had drastic effects on the coastal ocean and climate, 2) marine microbe sensors for early-detection of harmful algal species to safeguard aquaculture investments and livelihoods, and 3) online sensors for corrosion monitoring of subsea energy production and transportation infrastructure.******The developed microsensors will be integrated with autonomous water vehicles, like Argo floats and similar distributed networks, providing remote feedback on ocean chemistry and microbiology. Innovative in-situ sensors will enable us to safeguard human health, advance our knowledge of marine microbial/chemical processes, and be made aware of environmental issues before they are harmful and costly to remediate.**

与许多水生环境一样，由于目前的数据收集方法，海洋目前在空间（3D）和时间（+1D）上都采样不足。如果我们要对海洋中的重要问题进行观察、定性和干预，目前向海上派遣载人飞行任务的做法将不会很好地扩大规模。无人驾驶水上交通工具或海上无人机提供了在4D中执行远程采样和表征的能力，用于a）快速响应和B）大规模持久网络。然而，为这些海洋运载工具配备生物化学感测能力是具有挑战性的，因为商业上可获得的传感器：1）太大，2）太昂贵，以及3）太耗能。 需要逐步改变传感方法，以便从全球观测网络提供海洋化学和微生物学数据。在这一提议中，将探讨利用微流体系统和芯片实验室设备来改变目前获取海洋生物地球化学观测结果的做法。 廉价和多功能的海洋生物传感器将使我们能够快速，有效和准确地监测海洋生物地球化学在广泛的部署方案和一系列的位置。 这些微加工系统联合收割机结合了广泛的技术，通常集成了光学、流量控制和电子学。微流体平台自然有助于降低试剂和功耗，以及减小物理尺寸。然而，大多数微流体系统被设计用于标准压力和温度范围。很少有芯片实验室系统被设计用于深海部署。** 这项研究计划的重点将是创造关键的微制造组件，以允许深海部署的MEMS设备。这些水平推进器将允许进行几次海洋地球化学测量，并将为远程监测海洋内部开启一个可扩展的战略。 具体成果将包括：1）营养分析仪，用于监测对沿海海洋和气候产生严重影响的人类活动，2）海洋微生物传感器，用于早期检测有害藻类，以保障水产养殖投资和生计，以及3）在线传感器，用于海底腐蚀监测能源生产和运输基础设施。*开发的微传感器将与自主水上交通工具集成，如Argo浮标和类似的分布式网络，提供有关海洋化学和微生物学的远程反馈。创新的原位传感器将使我们能够保护人类健康，增进我们对海洋微生物/化学过程的了解，并在环境问题造成危害和昂贵的补救之前就意识到这些问题。