Offshore Resources
Offshore environments represent a significant and largely underexplored source of critical materials essential to energy, infrastructure, and advanced technologies. These resources occur in a range of settings, including seabed mineral deposits and subsurface systems. This focus area emphasizes integrated resource assessment, technology development, and environmental stewardship to enable responsible and sustainable offshore development.
Marine Critical Materials
Marine critical materials span a spectrum from coastal resilience and construction aggregates (sand, gravel) to deep-sea mineral resources (polymetallic nodules, sulfides, crusts). Together they underpin infrastructure, energy transitions, and high-tech manufacturing—but also raise significant environmental and governance challenges.
Key Contrasts: Coastal vs Deep Sea
Aspect | Coastal Sand/Placers | Deep-Sea Minerals |
| Scale | Massive (bulk materials) | Smaller but high-value metals |
| Depth | 0 – 200 m | 800 – 6,000 m |
| Use | Construction, coastal resilience projects | Energy expansion, technology |
| Maturity | Well established | Emerging/pre-commercial |
| Environmental Risk | Local/regional-scale | Potentially global/ecosystem-scale |
Technologies at the Jackson School of Geosciences
High-resolution 3D Marine Seismic Imaging (HR3D)
HR3D technology allows the subsurface to be imaged in unprecedented three-dimensional (3D) resolution using a high frequency acoustic source, high sample rate, and closely spaced short-offset streamers, resulting in small data bin size. Typically the upper meters to hundreds of meters of stratigraphy can be assessed, depending on source characteristics.
Coastal & Shallow Marine Resources
Marine Sand and Gravel
Unconsolidated sediments (quartz-rich sand, gravel)
Location
Nearshore seabed, Continental shelves, Coastal dunes and estuaries
Uses (high-volume, critical for society)
Construction aggregate (concrete, asphalt)
Land reclamation (e.g., Singapore, Dubai)
Beach nourishment & coastal protection
Glass manufacturing (high-purity silica sand)
Importance
Sand is the most extracted solid material globally after water
Marine sources are increasingly used due to depletion of river/quarry sand and Urbanization in coastal megacities
Risks
Coastal erosion and habitat loss
Turbidity impacts on fisheries and coral reefs
Altered sediment transport dynamics
Heavy Mineral Sands (Coastal Placers)
Titanium minerals: ilmenite, rutile
Zirconium: zircon
Rare earth-bearing minerals (monazite)
Uses
Titanium → aerospace, pigments
Zircon → ceramics, nuclear applications
Rare earths → magnets, electronics
Deep-Sea Mineral Resources
Polymetallic Nodules (Abyssal Plains)
Potato-sized nodules sitting on the seafloor (4,000–6,000 m depth)
Form over millions of years
Key metals
Manganese (Mn), Nickel (Ni), Copper (Cu), Cobalt (Co)
Strategic relevance
Critical for EV batteries (Ni, Co), Grid storage, Steel alloys
Issues
Habitat impact over vast areas
Slow ecosystem recovery
Seafloor Massive Sulfides (SMS) (aka polymetallic sulfides)
Formation
Around hydrothermal vents (mid-ocean ridges, back-arc basins)
Key metals
Copper, zinc, lead; Precious metals: gold, silver
Advantages
Higher grades than many land ores
More concentrated deposits
Challenges
Unique ecosystems (vent fauna)
Technically complex extraction
Limited commercial production to date
Cobalt-Rich Ferromanganese Crusts
Location
Seamounts (800–2,500 m depth)
Key metals
Cobalt, Nickel, REEs, Platinum
Importance
Cobalt is critical for Batteries, Aerospace alloys
Constraints
Difficult mining (hard substrate)
High ecological sensitivity of seamount habitats
Emerging Marine Critical Materials
Rare Earth Elements (REEs)
Location
Deep-sea muds (notably Pacific basins)
Some nodules and crusts
Importance
REEs are essential for Wind turbines, Electric vehicles, Electronics and defense systems
Marine Brines & Dissolved Resources
Lithium and other metals potentially extractable from seawater and subsea brines
Currently not widely economical, but under research
Strategic Importance of Marine Critical Materials
Energy Transition
Marine minerals supply key inputs for: Batteries (Ni, Co, Mn, Li), Renewable energy systems, Transmission infrastructure
Infrastructure & Urbanization
Marine sand is foundational for coastal resilience and concrete
Supply Chain Diversification
Deep-sea resources could reduce reliance on terrestrial mining (often geopolitically concentrated)
Environmental & Governance Considerations
Coastal Extraction Issues
Shoreline retreat
Loss of fisheries and habitats
Regulatory gaps in some countries
Deep-Sea Mining Concerns
Biodiversity loss in poorly understood ecosystems
Sediment plumes affecting large areas
Carbon cycling disruption
Governance Frameworks
International Seabed Authority (ISA) regulates deep-sea mining in international waters
National jurisdictions control coastal and shelf resources
