The location 65.476721-173.511416.-1125 represents a fascinating point on Earth that showcases the power of modern geographic positioning systems.
This unique coordinate marks a spot in the Northern Hemisphere, specifically 65.476721 degrees north of the Equator and 173.511416 degrees west of the Prime Meridian.
What makes this location particularly interesting is its depth of 1,125 meters below sea level, highlighting its underwater position in the vast ocean expanse.
The coordinates utilize the World Geodetic System 1984 (WGS84), which serves as the backbone for GPS technology and modern mapping systems. This location’s technical significance stems from its role in various applications, from oceanographic research to maritime navigation.
Understanding these coordinates is crucial for scientists, navigators, and researchers who rely on precise positioning data to conduct their work.
The decimal degree format of these coordinates ensures pinpoint accuracy, making it valuable for both practical applications and scientific studies.
This introduction sets the stage for a deeper exploration of how these coordinates impact our understanding of marine environments and their role in modern navigation systems.
Geographic Coordinates System
Latitude Analysis
The coordinate 65.476721°N places this location well within the Northern Hemisphere, specifically in a subarctic region. This latitude sits above the Arctic Circle (66.5°N), indicating an area characterized by extreme seasonal variations in daylight.
At this latitude, the location experiences the unique phenomenon of polar days in summer and polar nights in winter.
Longitude Position
At 173.511416°W, this point is situated in the Western Hemisphere, nearly at the international date line (180°). This longitude position places it in the far reaches of the North Pacific Ocean, where the Greenwich Meridian serves as the zero-reference point for measurement.
The location’s position near the date line makes it one of the last places on Earth to experience each new day.
Depth Analysis
The -1125m measurement indicates this is a deep-sea location, sitting well below sea level. This depth places it within the bathypelagic zone, also known as the midnight zone, where no natural light penetrates. At this depth, the environment is characterized by:
- High pressure conditions
- Near-freezing temperatures
- Limited biological activity
- Specialized marine ecosystems
The negative elevation suggests this point likely exists in a deep ocean trench or basin system, where unique deep-sea organisms have adapted to extreme conditions.
This depth is particularly significant for marine research and oceanographic studies, as it represents an environment where specialized deep-sea mining activities could potentially take place.
Environmental Characteristics
Marine Ecosystem
The Bering Sea location hosts a rich diversity of marine life. The area features all five Pacific salmon species, along with smaller fish like Pacific herring, anchovies, and sardines.
The deep waters at -1,125 meters exist in the bathypelagic zone, characterized by near-freezing temperatures and specialized deep-sea organisms. The ecosystem supports approximately 8,000 different species, including 2,000 phytoplankton taxa and over 4,500 benthic invertebrates.
Oceanic Features
The waters at this location experience unique characteristics. The salinity ranges from 31 to 33 parts per thousand at the surface, increasing to 35 parts per thousand near the bottom.
The area features a distinct three-layer structure: a warmer surface layer, a cold intermediate layer, and slightly warmer bottom waters. The location experiences significant seasonal variations, with complete ice coverage in winter and partial melting during summer months.
Bathymetric Profile
This point sits in the Bering Sea’s deeper region, specifically at -1,125 meters below sea level. The area is part of a complex underwater topography, where depths in the surrounding Aleutian Basin can reach between 12,000 to 13,000 feet.
The location exists in a transition zone between the shallower continental shelf, which averages about 500 feet deep, and the deeper basin areas. This depth zone is particularly significant for marine research and oceanographic studies, as it represents an environment where specialized deep-sea activities occur.
Technical Applications
Navigation Systems
The Global Positioning System at this location integrates with multiple navigation tools. The system uses at least 24 satellites to provide real-time positioning data through triangulation.
Modern vessels employ Electronic Chart Display Systems and Automatic Identification Systems that work together to ensure precise navigation in challenging waters. These systems achieve accuracy within 150 meters in real-time positioning.
Maritime Operations
Maritime operations heavily rely on integrated systems for safety and efficiency. The AIS transponder system operates in the VHF maritime band, enabling ship-to-ship and ship-to-shore communication.
This technology has helped reduce container losses in ports by 4-8% while increasing operational efficiency by 5-10%. The system provides crucial data about:
- Vessel identification
- Geographic location
- Cargo information
- Real-time movement tracking
Research Applications
The location’s depth of 1,125 meters makes it valuable for various research implementations. Oceanographers use advanced GPS data for:
- Underwater surveying
- Buoy placement
- Fish migration tracking
The integration of GPS technology with Geographic Information Systems (GIS) has revolutionized marine research capabilities.
Scientists can now track marine species movements with unprecedented accuracy, while commercial fishing fleets use this technology to optimize their operations and ensure compliance with fishing regulations.
The system supports approximately 8,000 different species monitoring, including 2,000 phytoplankton taxa studies in the region.
Location Significance
Oceanographic Importance
The location at 65.476721°N, 173.511416°W sits in the Bering Sea, one of the world’s most productive marine ecosystems. This area produces roughly 40% of all wild U.S. commercial fisheries and supports over 300 species of fish.
The depth of 1,125 meters places it in the bathypelagic zone, where unique deep-sea organisms thrive in near-freezing temperatures.
Scientific Research Value
This spot serves as a crucial point for studying marine ecosystems and climate change. Scientists monitor the seasonal sea ice patterns, which trigger important phytoplankton blooms each spring.
The location hosts approximately 8,000 different species, including 2,000 phytoplankton taxa and over 4,500 benthic invertebrates. The area’s significance extends to studying:
- Ocean circulation patterns
- Marine mammal migrations
- Deep-sea coral habitats
Maritime Navigation Relevance
The position holds strategic importance for maritime operations. The area experiences severe winter conditions with wave heights exceeding 40 feet and frequent storms.
A new system of two-way routes established by the IMO helps reduce marine casualties in this challenging region. The location serves as a critical point for:
- Vessel navigation
- Weather monitoring
- Ice coverage tracking
The spot’s proximity to the Bering Strait, the sole marine connection between the Pacific and Arctic Oceans, makes it vital for understanding ocean currents and climate patterns. The area experiences significant seasonal variations, with complete ice coverage in winter and partial melting during summer months.
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Data Implementation
Mapping Systems
Modern marine mapping uses advanced tools like multibeam sonar and side-scan sonar to create detailed seafloor maps. These systems can cover wide areas while traveling at speeds up to 10 knots, producing near real-time data that quickly transforms into usable maps.
The Geographic Information System (GIS) integrates with these tools to create comprehensive marine habitat maps that show both physical and biological characteristics of underwater environments.
GPS Integration
The integration of GPS technology with marine systems has revolutionized navigation accuracy and safety. Electronic Chart Display Systems work alongside Automatic Identification Systems (AIS) to provide real-time vessel tracking and positioning.
The system operates in the VHF maritime band, enabling both ship-to-ship and ship-to-shore communication while transmitting crucial data about vessel identification and location.
Coordinate Reference Frameworks
The World Geodetic System (WGS84) serves as the primary coordinate system for marine navigation. This system uses a combination of:
- Latitude measurements (65.476721°N)
- Longitude readings (173.511416°W)
- Depth calculations (-1125m)
The framework relies on the International Terrestrial Reference Frame (ITRF) for precise positioning. This system ensures accuracy within 150 meters in real-time positioning, making it essential for safe maritime operations.
The integration of these frameworks with modern mapping tools creates a comprehensive system for accurate marine navigation and research applications.
Practical Implications
Research Applications
The location serves as a crucial site for marine research, supporting over 600 peer-reviewed publications focused on the Bering Sea ecosystem.
Scientists study everything from phytoplankton diversity to marine mammal migrations, with approximately 8,000 different species under observation. The area produces roughly 40% of all U.S. commercial fisheries, making it vital for studying sustainable fishing practices.
Navigation Purposes
The International Maritime Organization established a system of two-way routes in this region to enhance maritime safety. These routes help reduce marine casualties in challenging conditions where wave heights can exceed 40 feet.
The location’s proximity to the Bering Strait, the sole marine connection between the Pacific and Arctic Oceans, makes it crucial for understanding ocean currents.
Environmental Monitoring
The site features comprehensive monitoring systems including:
Multibeam sonar for seafloor mapping
Satellite tracking of sea ice patterns
Real-time sensors measuring water quality
The monitoring efforts track rapid ecosystem changes, including coastal erosion, loss of sea ice, and changing fish distributions. These observations support both commercial activities and subsistence harvests that provide food for 55,000 Alaskan natives.
The location’s depth of 1,125 meters makes it ideal for studying deep-sea ecosystems and their response to climate change.
Future Considerations
Research Potential
The Northern Bering Sea research program has allocated $6.5 million for future studies focusing on ecosystem changes and their impacts.
The area’s significance for studying climate change and marine ecosystems continues to grow, with over 150 peer-reviewed publications already documenting crucial findings.
Future research will examine how environmental changes affect commercial fisheries and subsistence activities that provide food for more than 30 Alaska Native communities.
Technical Developments
The Environmental Sensing market is projected to reach $41.4 billion by 2029, growing at a 5.7% CAGR. New developments include:
IoT-enabled sensors for real-time data collection
Miniaturized sensors for drone deployment
Machine learning algorithms for predictive analysis
Environmental Monitoring
Future monitoring will focus on tracking rapid ecosystem changes, including:
- Sea ice loss patterns
- Fish population dynamics
- Coastal erosion rates
The integration of AI technology with environmental monitoring systems enables more precise tracking of ecosystem changes. New satellite remote sensing capabilities will provide continuous coverage of land use, atmospheric conditions, and ocean health.
The deployment of vast networks of IoT sensors will allow for immediate detection of environmental changes, supporting both commercial activities and subsistence harvests.
