The science behind NSPS
Exlterra’s NSPS (Nucleus Separation Passive System) is an unprecedented approach to radioactive and chemical soil decontamination. By targeting contaminants at the atomic level, NSPS transforms harmful substances into safe, stable forms within the soil matrix. This passive, energy-free system restores contaminated land sustainably, challenging conventional methods and expanding the boundaries of scientific understanding.
Core mechanism
At its core, NSPS operates by creating an environment that destabilizes contaminants at their nucleus. Using natural soil forces and engineered interactions, NSPS reduces the harmful properties of radioactive and chemical pollutants, converting them into inert, safe substances.
Nucleus separation explained
At the atomic level, radioactive and chemical contaminants emit energy due to unstable nuclei. NSPS influences these nuclei by subtly altering their interaction with the soil environment. This process changes the energy state of the contaminants, rendering them inert over time.
Stabilization through soil dynamics
NSPS enhances the natural binding and filtering properties of the soil. Contaminants are immobilized within the soil matrix, where they undergo gradual stabilization. This mechanism prevents their migration into groundwater or neighboring ecosystems.
Key principles at play
Subatomic interaction: NSPS triggers changes at the atomic level, disrupting the harmful energy emissions of contaminants.
Soil’s natural filtration: The system leverages soil’s innate ability to capture and neutralize particles, enhanced by NSPS’s unique configuration.
Passive energy forces: NSPS works with natural soil pressures and molecular forces to facilitate transformation without external inputs.
Chernobyl has symbolized the limits of human capability in addressing nuclear contamination for decades—until now. The installation of Exlterra's NSPS in the exclusion zone offers tangible hope. Using natural forces and scientific precision, this groundbreaking system accelerates the breakdown of radioactive isotopes without disturbing the soil. It marks a true shift in environmental technology, delivering measurable results in an area where no other solution has succeeded.
Excerpt from "Grounds for Freedom: Saving Chernobyl"
by R.J. King, Author
The NSPS technology is a revolutionary approach to radioactive soil decontamination. Unlike any method I have encountered in my career, it accelerates the natural decay process without chemicals, excavation, or disruption to the environment. It harnesses naturally occurring positrons and redirects their energy, and achieves what was previously deemed impossible: breaking down radioactive nuclei within contaminated soil. Its passive operation and long-term effectiveness present a sustainable, innovative solution to one of the world's most complex environmental challenges.
Environmental Scientist
Environmental Scientist, Kyiv Environmental Research Institute
Key components
Specialized engineered units
NSPS units are crafted from advanced, chemically inert materials designed to enhance soil interactions at the molecular level.
Durability
The NSPS units resist chemical and environmental degradation, ensuring long-term effectiveness in contaminated sites.
Sustainability
NSPS operates without energy or external chemical inputs, providing a cost-effective, eco-friendly alternative to traditional methods.
Resilient under extreme conditions
Performs reliably across a wide range of temperatures and environmental factors, ensuring consistent decontamination.
Energy-free operation
Relies entirely on natural soil processes to neutralize contaminants, requiring no external energy or power sources.
Modular adaptability
Customizable configurations allow NSPS to address contamination in diverse environments, from industrial sites to agricultural fields.
Non-invasive installation
Installed below the surface with minimal disruption, preserving existing vegetation and soil structure.
Step-by-step natural process
Contaminant immobilization
Once installed, NSPS units create a localized environment that captures and immobilizes radioactive and chemical particles within the soil.
Subatomic destabilization
Through passive energy forces, contaminants undergo gradual nucleus separation, reducing their harmful properties.
Safe transformation
Over time, the contaminants are rendered inert, breaking down into stable, harmless components naturally retained in the soil.
Long-term containment
NSPS ensures that transformed contaminants remain localized and stable, preventing leaching or environmental harm.
Integration with natural systems
NSPS enhances the soil’s existing filtration and stabilization processes by immobilizing contaminants to prevent migration, gradually neutralizing harmful particles, and restoring soil health without excavation or disruption.
Before
After
Cross-section of a NSPS unit
Further technical questions
Real-world validation
Field tests demonstrate the effectiveness of NSPS in reducing radioactive and chemical contamination. Results show significant decreases in contamination levels within the first year of installation, providing a permanent, maintenance-free solution to previously intractable environmental challenges.
