The use of the abundant and easily available solar energy is central towards a carbon-free society and represents the most sustainable strategy for the increasing energy demand. Rhodobacter (R.) sphaeroides is a versatile photosynthetic purple non sulfur bacteria able to harvest sunlight, particularly in the Near InfraRed (NIR) region, and to efficiently transform it into photochemical energy. In this work, whole wild-type, metabolically-active photosynthetic bacterial cells of R. sphaeroides , and their carotenoid-less mutant strain, were integrated in a two-electrode architecture, to output a positive photovoltage upon illumination. The photovoltage amplitude of the mutant strain is almost three times higher than that obtained with wild-type cells. Photosynthetic bacteria were also integrated in a light-electrolyte-gated organic transistor to produce a photomodulated electronic current, as well as in a biophotonic power cell working on direct sunlight. This proves that bio-organic hybrid optoelectronic devices may enable environmentally safe and cost-effective energy production.
Bio-hybrid Photovoltaic devices operated on living photosynthetic bacteria / Labarile, R.; De Salvo, A.; Rondelli, F.; Giangregorio, M. M.; Di Lauro, M.; Trotta, M.; Farinola, G. M.; Biscarini, F.. - In: BIOSENSORS & BIOELECTRONICS. - ISSN 0956-5663. - 295:(2026), pp. 118260-118260. [10.1016/j.bios.2025.118260]
Bio-hybrid Photovoltaic devices operated on living photosynthetic bacteria
Di Lauro M.
;Biscarini F.Supervision
2026
Abstract
The use of the abundant and easily available solar energy is central towards a carbon-free society and represents the most sustainable strategy for the increasing energy demand. Rhodobacter (R.) sphaeroides is a versatile photosynthetic purple non sulfur bacteria able to harvest sunlight, particularly in the Near InfraRed (NIR) region, and to efficiently transform it into photochemical energy. In this work, whole wild-type, metabolically-active photosynthetic bacterial cells of R. sphaeroides , and their carotenoid-less mutant strain, were integrated in a two-electrode architecture, to output a positive photovoltage upon illumination. The photovoltage amplitude of the mutant strain is almost three times higher than that obtained with wild-type cells. Photosynthetic bacteria were also integrated in a light-electrolyte-gated organic transistor to produce a photomodulated electronic current, as well as in a biophotonic power cell working on direct sunlight. This proves that bio-organic hybrid optoelectronic devices may enable environmentally safe and cost-effective energy production.
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