The goal of this SERDP Exploratory Development (SEED) project was to develop a visible obscurant using low toxicity TiO₂ particles that improves upon the performance of existing powder based visible obscurant grenades by a factor of 5. This goal was achieved by chemically and physically improving the dry powder fill material in a TiO₂ grenade and investigating new methods of disseminating TiO₂ nanoparticle to reduce agglomeration when aerosolized.

Several methods to synthesize TiO₂ were developed and evaluated. One method produced stable monodisperse particles with mean diameters of 20 nm and 20% coefficient of variation (CV) and another method yielded discrete 184 nm diameter particles with an 18% CV. A variety of commercially available TiO₂ powders were also acquired, processed, and functionalized with surface chemistries designed to minimize surface adhesion and to optimize dissemination. Uncoated TiO₂ particles are hydrophilic and, after coating with long chain silane groups, can be rendered hydrophobic which improves their dispersibility. Techniques for coating TiO₂ particles in solution and as a dry powder were successfully developed.

A wide variety of surface modified TiO₂ powders were packed at precisely controlled pressures into various container geometries. The packed powders were disseminated into a custom built 2.5 m³ aerosol chamber using various dispersal methods that are optimized to generate high shear forces and minimize the agglomeration of the aerosolized materials. The high improvement due to surface functionalization was Tiona RCL-9 TiO₂ (Cristal Global) coated in solution with cyclic azasilanes, lyophilized to remove the solvent without agglomerating the nanomaterials, compressing into a thin puck using a ram with 500 psi pressure, and pneumatically disseminating with a burst of 1000 psi air. Using this optimized approach, gFOMs of up to 4 m²/cm³ were obtained compared to 0.6 m²/cm³ for the currently fielded M106 grenade (a factor of 6 improvement).

The performance gains were obtained using surface coatings on commercially developed powders that were still agglomerated, and continued improvement in deagglomerating commercial powders followed by surface functionalization and effective dissemination has the potential to increase performance closer to the theoretical gFOM for TiO₂ based smokes which is 25 m²/cm³. If successful, such improvements would allow for the generation of a rapid, safe, and effective new class of obscuration devices that would exceed HC based obscurant devices in performance.

(Project Completion-2012)