KNI Nils Asplund FAST Prize Seminar: "Porous Silica Scaffolds Enable Mechanically Robust Simulated Hydrothermal Chimney Growth"

KNI Special Seminar

"Porous Silica Scaffolds Enable Mechanically Robust Simulated Hydrothermal Chimney Growth"

Seneca Velling, Caltech and NASA Jet Propulsion Laboratory

Wednesday, December 3

3 pm

125 Steele Laboratory

Refreshments in Steele Lobby after the talk

Abstract

Injection chemical garden experiments have been used to produce laboratory analogs to seafloor hydrothermal chimneys on Earth and ocean worlds. These systems form self-assembled inorganic membranes via precipitation of metal oxyhydroxides, silicates, and/or sulfides when a hydrothermal fluid simulant is slowly injected into a seawater simulant. In certain reaction systems, this nonequilibrium precipitation generates fragile structures, which exhibit microstructural weakness from multiple competing crystallites, nonepitaxial growth, loose agglomeration, and poor sintering of particles, hindering the extraction and study of the chimneys. 

To improve control and robustness of simulated chimney structures, we developed a new method of precipitating chemical gardens within 3D scaffolds composed of hydrothermally relevant minerals (e.g., opal-A), in order to enable intact extraction and improved in situ and ex situ characterization of the precipitated structures. The scaffolds were fabricated by using vat stereolithography, allowing tailored control over the direction of the precipitation reaction front. We tested three open-cell architectures of scaffolds (square cubic, inverse opal, and Voronoi) that facilitated the flow-through of hydrothermal fluid simulant and structurally supported the precipitated hydrothermal chimneys. Using mineral fillers to provide surface roughness for nucleation, our scaffolds permitted stable growth of hydrothermal chimney analogs at accelerated rates up to 3 mL/min (∼40–500×) compared to previous lab-scale analogs. 

These 3D flow-through scaffolds successfully augmented injection chemical garden experiments, simulating hydrothermal chimneys by providing architectural strength for more physically stable chimney growth. This enhanced precipitate stability opens future avenues for studying the growth, evolution, and alteration of simulated hydrothermal precipitates.

Speaker

Seneca J. Velling is a Ph.D. candidate in Materials Science at Caltech, advised by Profs. Rossman & Faber (Caltech) and Drs. Barge & Weber (NASA Jet Propulsion Laboratory). He conducts his research in the Origins and Habitability Laboratory through the JPL Visiting Student Research Program (JVSRP). Seneca is a recent NASA NSTGRO Fellow and the recipient of the 2024 KNI Nils Asplund FAST Prize; he will present the results of this collaborative project at the semi