Artificial aerosols, microscopic particles capable of reflecting solar radiation
in the atmosphere, can be sprayed at high altitudes to achieve rapid
cooling effects. However, this counterproductive human intervention,
while temporarily reducing atmospheric temperatures, actually
accelerates ocean warming, leading to severe disasters in fisheries.
As a result, numerous marine species including shellfish, seabirds,
lobsters, cod, sea lions, seals, and whales have perished.
Pathways of Artificial Aerosols
Once introduced into the atmosphere, artificial aerosols typically undergo
three stages: 1. Slow movement in the stratosphere; 2. Rapid descent
in the troposphere; 3. Floating and sinking in the ocean. The
duration of these stages varies based on local air currents, ocean
currents, temperature, season, and geography. Regardless of the time
involved, the aerosols' interaction with solar radiation—reflecting,
refracting, scattering, and backscattering—creates varying scales
of radiant heat zones across the atmosphere, surface water, and
underwater.
Dual-Layer Radiant Heat Effect
Upon entering the ocean, artificial aerosols float on the surface for a
period before sinking. As they move with ocean currents, they either
disperse or accumulate. When aerosol particles reach a certain
density on the surface, the intense reflection of solar radiation
generates a heat radiance that elevates sea surface temperatures.
Some of the penetrating sunlight interacts with underwater aerosol
particles and lower-level water surfaces in complex patterns of
reflection and refraction. This dual-layer radiant heat effect traps
the ocean on a one-way path to irreversible warming.
Ocean Hotspots - The Cancer within the Sea
Artificial aerosols are not the primary culprits behind marine disasters but are
rather the result of poorly considered actions within net-zero
emissions projects, inadvertently accelerating the warming of oceanic
pathways. Today's oceans, akin to the Earth's dumpsites, receive all
toxic waste from the atmosphere, land, and rivers. The increasingly
hot, acidic, and oxygen-deprived waters catalyze unpredictable
chemical reactions, devouring life around them like cancer cells,
spreading rapidly and visibly even from satellite imagery - these are
the ocean hotspots.
Emergency Ocean Aid: Hydrogen and Oxygen Needed
Facing unprecedented levels of pollution, the ailing ocean has lost its
natural purifying ability and is in desperate need of rescue.
Addressing each pollutant individually might seem too slow and
resource-intensive without guaranteeing results. A more viable
approach would focus on reigniting the ocean's self-healing
capabilities. Just as a healthy human body detoxifies, purifies, and
regenerates, a high concentration of oxygen and hydrogen could
strengthen marine life functions and reboot the ecosystem, urgently
necessitating CPR for the dying ocean.
A New Dawn with Matter-Energy Conversion Technology
Deoxygenation,hydrogen deficiency, acidification, and high temperatures laden with
toxins create a domino effect propelling us toward a climatic tipping
point. Preventing the continuous collapse of marine ecosystems hinges
on two crucial factors: removing toxins and increasing the
concentration of oxygen and hydrogen in seawater. Should a novel
technology capable of restructuring molecular pollutants to convert
them into hydrogen and oxygen emerge, it could simultaneously address
these critical challenges, shining a ray of hope on marine pollution
control.
CRCS Marine Carbon Pollution Solution
Our strategic approach to technology employs Removal, Conversion, and
Reduction.
The CRCS, a cutting-edge negative carbon technology driven by
ultra-photonic vibration, restructures CO2e molecules into hydrogen
and oxygen. This system, requiring no capture, storage, or chemical
processing, covers atmospheric, terrestrial, and aquatic
environments, aligning with high efficiency, low carbon emissions,
minimal material use, zero waste, and high recovery rates—hallmarks
of sustainable operations.
Expanding the CRCS Scope
To address the vast expanse of the world's oceans, comprehensive marine
carbon pollution removal must simultaneously execute three
construction strategies: Fixed-Site, Liquid-Type, and Deployment.
1.Fixed-Site Construction:
CRCS systems are deployed along major ocean currents, performing carbon
dioxide conversion within effective ranges and using ocean
circulation as a super conveyor belt to distribute 'healed' water
across marine areas, thereby restoring the ocean's health from points
to lines to circles.
2.Liquid-Type Construction:
The CRCS systems are installed on various large waterborne vessels, such
as yachts, cruise ships, fishing vessels, and cargo ships, using
their routes to create an extensive network of carbon conversion,
with large cargo ships additionally reducing their own carbon
emissions.
3.Put in:
CRCS systems, requiring no electricity and operational for over a century
in soil and seawater, are deployed across ocean floors, ideally at
depths of 1200 meters where they are most effective, increasing
density in these regions to significantly enhance carbon pollution
conversion rates and balance seawater acidity.
Triple Overlapping Effect
Utilizing fixed-site, mobile, and deployment configurations, we generate an
invisible toroidal field (Torus) within the effective range. This
system synchronously processes carbon removal from the sky, soil, and
oceans while integrating ocean currents, shipping routes, and a
checkerboard configuration of bases, culminating in the most
comprehensive oceanic carbon removal model.
Scale of Installation
The scale of removal and conversion is directly proportional to the
number of installations. For instance, in the South Atlantic, using
minimal standards, the coastal fixed-site installation requires 36
units, the mobile installation requires 20-30 vessels on fixed
routes, and the ocean deployment demands 70-80 CRCS units.
Considering resource allocation, ocean deployment may be prioritized.
Annual Performance Estimates
For the South Atlantic carbon removal model, the estimated CO2e removal
is between 45-55%, with an oxygen-hydrogen enhancement rate of
60-70%, and an acidification balance rate of 60-70%. These figures
are from EQT’s marine carbon removal research team, and EQT is keen
to collaborate with third-party institutions for physical
verification.
The health of the ocean directly affects the habitability of our planet.
We must exert our utmost efforts before reaching the critical
juncture of climate change, with a focus on maintaining ocean health.
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#https://www.eqt-netzero.com/