Incorporating neuromorphic electronics in bioelectronic interfaces can provide intelligent
responsiveness to environments. However, the signal mismatch between the environmental …

Memristive devices are promising candidates to emulate biological computing. However, the
typical switching voltages (0.2-2 V) in previously described devices are much higher than …

An efficient strategy for addressing individual devices is required to unveil the full potential of
memristors for high‐density memory and computing applications. Existing strategies using …

Harvesting energy from the environment offers the promise of clean power for self-sustained
systems 1 , 2 . Known technologies—such as solar cells, thermoelectric devices and …

Biological sensory organelles are often structurally optimized for high sensitivity. Tactile
hairs or bristles are ubiquitous mechanosensory organelles in insects. The bristle features a …

Employing renewable materials for fabricating clean energy harvesting devices can further
improve sustainability. Microorganisms can be mass produced with renewable feedstocks. …

Memristors are promising candidates for constructing neural networks. However, their dissimilar
working mechanism to that of the addressing transistors can result in a scaling mismatch…

Electronic sensors based on biomaterials can lead to novel green technologies that are low
cost, renewable, and eco-friendly. Here we demonstrate bioelectronic ammonia sensors …

Sustainably produced biomaterials can greatly improve the biocompatibility of wearable
sensor technologies while reducing the energy and environmental impacts of materials …

Commercial, industrial, and military aerospace designs are increasingly deploying MEMS
micro inertial measurement unit (MIMU) for motion control, automation, and positioning …