SoilTech is diluted directly into the water truck and sprayed onto the scarified soil surface. The treated layer is then homogenized using graders or soil-recycling equipment and compacted to the target density using standard earthwork equipment already available on site.

Because SoilTech is fully soluble in water, no pre-mixing plants or specialized mixing systems are required. Typical field dosage ranges from 0.01–0.03% by dry soil mass, depending on soil conditions and project requirements. Laboratory testing is recommended before application to define dosage and expected performance.

Traditional stabilization methods often require large volumes of imported aggregates or cement to achieve the required structural performance. Aggregates can require 15–30% volumetric replacement, while Portland cement commonly ranges from 2–10% by weight depending on the soil type and engineering design.

SoilTech is typically applied at only 0.01–0.03% by dry soil mass and can improve compaction efficiency, reduce permeability, and increase mechanical performance while using existing in-situ soils.

When combined with aggregates or cement, SoilTech can reduce aggregate consumption by 30–50% and cement usage by 50–95%, helping lower logistics costs, operational costs, and CO₂ footprint while maintaining project performance requirements.

SoilTech can be evaluated for sandy, silty, clayey, lateritic, granular, and mixed soils, including projects involving aggregates and mining materials.

Performance depends on soil composition, moisture conditions, particle size distribution, and project requirements. Laboratory testing is recommended before full-scale application to determine the optimal dosage, moisture conditions, and expected engineering performance.

SoilTech is applied using traditional earthwork and road stabilization equipment already available on most project sites, including water trucks, motor graders, soil recyclers, harrow tractors, and vibratory rollers.

Because the product is fully water-soluble, it is incorporated directly into the water truck without the need for pre-mixing plants, specialized batching systems, or dedicated stabilization fleets. This simplifies logistics and makes SoilTech suitable for remote projects and operational sites with limited infrastructure.

Yes. Derived from seaweed, it has no known toxicity to soil organisms or vegetation. Ecotoxicity tests conducted with the product demonstrated the absence of significant adverse effects on test organisms and indicated environmental compatibility for soil application, reinforcing its non-toxic and bio-based profile when compared to conventional lime- and cement-based methods.

Yes. SoilTech can be used standalone or combined with lime, cement, or aggregates depending on the engineering requirements of the project.

When combined with traditional stabilization materials, SoilTech can help reduce aggregate consumption by 30–50% and cement usage by 50–95%, depending on soil conditions, design specifications, and laboratory results.

Laboratory testing is recommended to determine the optimal dosage and stabilization design for each project.

SoilTech-treated soils can be evaluated using ASTM D421 (Soil Characterization), ASTM D698 (Standard Proctor Compaction), ASTM D1883 (CBR), ASTM D4318 (Atterberg Limits), ASTM D2166 (Unconfined Compressive Strength), and ASTM D1556 for in-situ density verification.

Pre-application laboratory testing is recommended to confirm dosage, moisture conditions, and expected engineering performance before full-scale application.

Yes, both permanent and temporary. For paved roads, SoilTech is applied to the subgrade or subbase ahead of asphalt or concrete surfacing. For permanent unpaved roads like mine haul routes and agricultural logistics roads, it stabilizes the wearing course directly, extending structural life and reducing maintenance frequency.

Lab testing confirms soil compatibility, determines the right dosage rate, and verifies that specified CBR and compaction results will be achieved at full scale. Without it, there's a risk of under-application (insufficient performance) or over-application (unnecessary cost).