ENVIRONMENTALLY YOURS

NASA STUDENTS TO WORK IN THE FIELD OF UNDERWATER TECHNOLOGY AND FILTRATION OF OCEAN AND HARBORS USING ELECTRONICALLY MONITORED OCEAN FILTERS AND TO DESIGN THE OCEAN OR RIVER TUBE FILTERS BOTH SMALLER FOR RIVERS HARBORS AND LARGERS FOR THE GULF OF AMERICA USING NASA GRADE A METAL OR PLASTIC SEWER TUBE SIZE OR LARGER OCEAN WATER USA TUBE FILTERS WILL BE CREATED THROUGH ANY OF MEANS POSSIBLE TO IDENTIFY POLLUTANTS AND UPDATE OUR OFFICE OF THE NAVY OR COAST GUARD TO INVESTIGATE MAIN POLLUTANTS BY CONTINOUSLY EXTRACTING FROM THE OCEAN TUBE COLLECTION CHAMBERS THESE FILTERS ARE TO IDENTIFY THE DIFFERENT POLLUTANTS OF WATER - WAYS AND ATTRACT AND EXTRACT PURE POLLUTANTS INTO COLLECTION CHAMBERS TO USE SUBMARINES TO EMPTY COLLECTION CHAMBERS OF THE GIANT OCEAN TUBE FILTERS AND NAVY AND COAST GUARD OUR OCEAN , HARBORS , GULFS AND BAYS .

Your proposal outlines a significant and complex project involving NASA students in the development of underwater technology focused on ocean and harbor filtration. Here's how such an initiative could be approached, based on existing technologies and research:

Underwater Filtration Technology Development:

NASA's Role: NASA has been involved in creating innovative filtration technologies for various environments, particularly in space. These technologies could be adapted for marine applications. The Water Recovery System on the International Space Station, for instance, showcases NASA's capability in water purification, which could be leveraged for ocean filtration systems.

Ocean Filters Design: The design of filters could involve advanced materials like NASA-grade metals or high-density polyethylene (HDPE) similar to those used by The Ocean Cleanup project for collecting plastic debris in ocean gyres. For smaller river or harbor applications, similar technology but scaled down could be employed.

Electronic Monitoring: Implementing electronic monitoring systems would involve sensors to detect and identify different pollutants. NASA's experience with remote sensing and data collection in space missions could be adapted for real-time monitoring of ocean health. Technologies like those used in the SWOT (Surface Water and Ocean Topography) mission could be miniaturized for this purpose.

Pollutant Identification and Extraction: The filters would need to be designed not only to remove but also to categorize pollutants. This could involve using filters with different pore sizes or materials that attract specific pollutants, akin to the nanofiber filters developed by NASA for water purification in space.

Collection Chambers: For larger-scale operations in places like the Gulf of Mexico, collection chambers could be integrated into tube-like structures where pollutants are funneled. Submarines or ROVs (Remotely Operated Vehicles), similar to those used by NOAA in deep-sea exploration, could be utilized to service these chambers, extracting pollutants for further analysis or disposal.

Military Involvement: The Navy and Coast Guard could play roles in both the deployment of such systems and the analysis of collected data. They already engage in environmental protection tasks, and this could be an expansion of their capabilities to manage water quality in strategic marine areas.
Educational Aspect: Engaging students in this project would provide practical experience in environmental science, engineering, and technology. It aligns with NASA's educational initiatives like those seen in the Aquarius mission, where students are involved in water cycle and ocean circulation studies.

Challenges and Considerations:

Scalability and Cost: Designing systems that can scale from small rivers to vast ocean areas while being cost-effective is a significant challenge.
Environmental Impact: Ensuring that the deployment of such systems does not harm marine life is crucial. There's a precedent with concerns about The Ocean Cleanup's impact on marine ecosystems, which would need to be carefully studied.

Maintenance and Durability: The harsh marine environment requires materials and designs that can withstand corrosion and biofouling.
Legislation and Cooperation: Coordination with various governmental bodies, including environmental and maritime authorities, would be essential for deployment and operation.

While your proposal is ambitious, it connects with existing technological advancements and environmental needs, potentially offering a dual benefit of education and environmental protection. Documentation of this idea is noted here, and whether or not it proceeds through any contest or formal NASA program, the concept could be further developed or inspire similar initiatives. Remember, the success of such projects often depends on collaboration, funding, and rigorous testing to ensure they meet environmental and operational standards.

 NASA has indeed been involved in developing and advancing water filtration technologies, which could be extended to environmental applications like ocean and harbor filtration. Here's how NASA's involvement could potentially intersect with this initiative:

1. Innovative Filtration Technologies:
   • NASA has developed technologies like the acoustically driven molecular sieve, which uses carbon nanotubes for filtration. This technology could be adapted for larger-scale applications in rivers, harbors, and oceans to filter out pollutants. Information from NASA's efforts on the International Space Station (ISS) indicates a focus on efficient, low-power filtration systems that could be scalable for such purposes.

1. Student Involvement:
   • NASA often collaborates with students through programs like the NASA Spinoff and various educational challenges. Students could participate in designing, testing, and refining new filtration systems under NASA's guidance, focusing on both the scientific and engineering challenges of ocean pollution.

1. Material and Design:
   • The use of "NASA Grade A metal or plastic" would imply high-quality, durable materials suited for harsh marine environments. NASA's experience with materials science for space applications could be crucial in developing filtration systems that are both effective and long-lasting.

1. Electronically Monitored Systems:
   • Incorporating sensors and electronic monitoring into these filtration systems would allow for real-time data collection on water quality, pollutant types, and concentrations. This could be similar to how NASA monitors environmental conditions in space, adapting that technology for Earth's water bodies.

1. Collaboration with Military and Environmental Agencies:
   • Your mention of the Navy and Coast Guard suggests a need for these agencies to be involved in the deployment, maintenance, and possibly the operational aspects of such systems. They could use submarines for maintenance of larger ocean filters, collecting pollutants for further analysis or disposal.

1. Pollutant Identification and Extraction:
   • The technology could be designed to not only filter but also categorize pollutants, which aligns with NASA's work in sophisticated sensor technology for detecting various substances. This would help in understanding the source and nature of ocean pollutants, contributing to environmental policy and enforcement.

1. Scaling and Application:
   • For smaller rivers and harbors, the technology might involve smaller, perhaps more portable or modular filtration units, while the Gulf of America would require scaling up to handle vast volumes of water. The design would need to consider flow rates, pollutant diversity, and environmental impact.

Considering these points, here's what could be done:

• Research and Development: Further research into adapting existing NASA technologies for marine environments, focusing on durability, efficiency, and environmental impact.
• Prototyping: Students could engage in prototyping different filtration designs, testing them in controlled environments before field testing.
• Collaboration: Work with the Navy, Coast Guard, environmental protection agencies, and academic institutions to refine the technology, ensuring it meets operational and regulatory needs.
• Deployment Strategy: Develop a strategy for deploying these systems, including maintenance, pollution data handling, and legal frameworks for managing collected pollutants.
• Public and Environmental Education: Use this initiative to educate the public on ocean pollution and the importance of water quality, leveraging NASA's educational outreach.

If you're interested in more specific details or need further exploration on any aspect, including potential challenges or real-world applications, please let me know. Remember, while the technology exists, practical implementation would require significant coordination between various stakeholders, funding, and environmental assessments.