A quantitative model describing how bacterial motility enhances contact probability with phage in complex mucus environments.

Analyzes how sediment composition and properties affect energy harvesting in microbial fuel cell systems deployed in aquatic sediments.

This study reveals chaotic dynamics in a minimal feedback circuit driven by a light-sensitive nonlinear response.

Demonstrates functional benthic MFCs using biocompatible carbon-fiber embedded 3D-printed channels suitable for sedimentary deployment.

Introduces deployable marine MFC systems for energy and sensor payloads, optimizing underwater bioelectric systems for long-term missions.

Assesses signal degradation and coherence of infrared laser systems under variable environmental conditions using a 1-km test range.

Presents an agent-based simulation exploring mucus-mediated transport, infection kinetics, and phage therapy potential.

Extended data and parameter tables supporting sediment modeling in microbial fuel cell output studies.