Point-of-use printed nitrate sensor with desalination units.

Nitrate is an important marker of water quality that can be challenging to detect in seawater due to the presence of multiple chemical interferants and high background chloride. Here, we demonstrate a compact microfluidic device that incorporates electrochemical desalination to selectively remove the interfering chloride ions and improve the detection limit of the downstream potentiometric nitrate sensor. The microfluidic platform was fabricated by a low-cost cut-and-lamination approach, and the detection mechanism was based on potentiometric measurements at an Ag/AgCl electrode coated with a nitrate-selective membrane. The sensor system achieved a detection limit of 0.5 mM with a sensitivity of 11.3 mV/dec under continuous flow.

Retinomorphic Motion Detector Fabricated with Organic Infrared Semiconductors.

Organic retinomorphic sensors offer the advantage of in-sensor processing to filter out redundant static backgrounds and are well suited for motion detection. To improve this promising structure, here, the key role of interfacial energetics in promoting charge accumulation to raise the inherent photoresponse of the light-sensitive capacitor is studied. Specifically, incorporating appropriate interfacial layers around the photoactive layer is crucial to extend the carrier lifetime, as confirmed by intensity-modulated photovoltage spectroscopy. Compared to its photodiode counterpart, the retinomorphic sensor shows better detectivity and response speed due to the additional insulating layer, which reduces the dark current and the RC time constant. Lastly, three retinomorphic sensors are integrated into a line array to demonstrate the detection of movement speed and direction, showing the potential of retinomorphic designs for efficient motion tracking.

Multiplexed printed sensors for in situ monitoring in bivalve aquaculture.

Non-intrusive sensors that can be attached to marine species offer opportunities to study the impacts of environmental changes on their behaviors and well-being. This work presents a thin, flexible sensor tag to monitor the effects of dissolved oxygen and salinity on bivalve gape movement. The measurement range studied was 0.5-6 ppm for the dissolved oxygen sensor and 4-40 g kg-1 for the salinity sensor. The curvature strain sensor based on electrodeposited semiconducting fibers enabled measurements of an oyster's gape down to sub-mm displacement. The multiplexed sensors were fabricated by low-cost techniques, offering an economical and convenient platform for aquaculture studies.

Correction: Patterned liquid metal contacts for high density, stick-and-peel 2D material device arrays.

Correction for 'Patterned liquid metal contacts for high density, stick-and-peel 2D material device arrays' by Yen-Lin Chen et al., Nanoscale, 2018, 10, 14510-14515.

Patterned liquid metal contacts for high density, stick-and-peel 2D material device arrays.

Two-dimensional materials have shown great promise to enable novel wearable electronic devices ranging from sensors to energy generators. These developments are due to their high mechanical robustness, which allow them to retain high performance even at large deformations. Under these conditions, however, good electrical contacts become an important issue that cannot be addressed with conventional materials. Liquid metals could overcome this limitation by providing soft and compliant electrodes but to date no realistic heterointegration of nanomaterials and complex liquid metal contacts has been attempted. We here demonstrate the application of micrometer-sized electrical contacts to flexible, fragile and rough 2D materials using patterned liquid metal contacts. A novel deposition method enables the scalable and facile production of large arrays of contacts in arbitrary geometries. This ability permitted the single-step, fabrication-free and contamination-free production of concentric liquid metal-contacted graphene field effect transistors of comparable performance to traditional devices. We demonstrate that the contacts can be removed without damaging the 2D materials allowing the contacts to be reused. Finally, good contact could be made to complex morphologies and three-dimensional substrates, which highlights the potential of our approach to the characterization and application of nanomaterials in electronics.