Semiconducting bacterial biofilm based on graphene-MoS2 template and component dependent gating behavior

Abstract: In this paper, we report for the first time, the synthesis of a semiconducting biofilm. Photosynthetic bacterial biofilm has been used to weave together MoS2 nanosheets into an adherent film grown on interdigitated electrodes. Liquid-phase exfoliation of bulk MoS2 powder was used to obtain MoS2 nanosheets. A synchronous-fluorescence scan revealed the presence of two emission maxima at 682nm and 715nm for the MoS2 suspension. Such maxima with bandgap energy 1.82 and 1.73 eV corresponded to the single and double… Show more

“…Therein, nanomaterials with biocompatibility and high electrical conductivity are used to develop self-sustaining heterojunctions that ensure efficient EET processes. A series of investigations on abiotic/biotic coupling heterojunctions (e.g., nanostructured polymer−biofilms and/or graphene/ CNTs−enzymes, Table 1) revealed that overlapping heterojunction structures favored microbial substrate utilization and charge transfer, thereby boosting bio-electricity generation (Lv et al, 2018;Ray et al, 2020;Su et al, 2020;Zhao et al, 2015a). In particular, multiple lines of orbits constructed in these overlapping heterojunction architectures are mostly layer-ordered, multidirectional and highly conductive, thereby favoring the transport of microbial substrates and boosting surface/interface dynamic reactions (Wang et al, 2016;Xie et al, 2015).…”

Modular configurations of living biomaterials incorporating nano-based artificial mediators and synthetic biology to improve bioelectrocatalytic performance: A review

“…Therein, nanomaterials with biocompatibility and high electrical conductivity are used to develop self-sustaining heterojunctions that ensure efficient EET processes. A series of investigations on abiotic/biotic coupling heterojunctions (e.g., nanostructured polymer−biofilms and/or graphene/ CNTs−enzymes, Table 1) revealed that overlapping heterojunction structures favored microbial substrate utilization and charge transfer, thereby boosting bio-electricity generation (Lv et al, 2018;Ray et al, 2020;Su et al, 2020;Zhao et al, 2015a). In particular, multiple lines of orbits constructed in these overlapping heterojunction architectures are mostly layer-ordered, multidirectional and highly conductive, thereby favoring the transport of microbial substrates and boosting surface/interface dynamic reactions (Wang et al, 2016;Xie et al, 2015).…”

Modular configurations of living biomaterials incorporating nano-based artificial mediators and synthetic biology to improve bioelectrocatalytic performance: A review