Photobioelectrochemical systems (PBEs) harness the machinery of photosynthetic microorganisms to convert solar energy into electricity. However, the inefficient electron transfer at the cell-electrode interface remains as the key performance limitation. Herein, we report a plasmonic biohybrid strategy to enhance extracellular electron transfer in Chlorella -based photobioelectrodes by integrating gold nanoparticles (AuNPs) localized on the microalgae membrane. Two approaches are investigated, consisting of physical mixing of isolated cells with AuNPs and cultivating microalgae in a growth medium supplemented with AuNPs, with the second approach allowing to obtain about significantly higher photocurrent responses. Optimized bioelectrodes yield photocurrent densities of up to 132 μA cm −2 , 74% higher than bioelectrodes fabricated using unmodified cells. Spectral response analysis reveals a strong resonance at 525 nm, consistent with the plasmonic properties of AuNPs. Importantly, pigment content, growth kinetics, and membrane integrity are preserved, confirming the biocompatibility of the modification. This work presents a facile and effective route to engineer photosynthetic bioelectrodes using nanomaterials, advancing the design of high-performance PBEs for solar-to-electricity conversion. • Microalgae cell membrane-bound AuNPs boost photocurrent by up to 74%. • Plasmonic resonance at 525 nm enhances light absorption and ET efficiency. • Non-genetic strategy preserves cell viability, pigments, and growth rate. • AuNPs act as conductive bridges, strengthening ET pathways. • Hybrid photobioelectrode offers a simple, scalable route to more efficient activity.
Silva et al. (Sun,) studied this question.