Connecting wastes to resources for clean technologies in the chlor-alkali industry: a life cycle approach

Our current economic model is experiencing increasing demand and increasing pressure on resource utilisation, as valuable materials are lost as waste. Moving towards a circular economy and supporting efficient resource utilisation is essential for protecting the environment. The chlor-alkali industry is one of the largest consumers of salt, and efforts have been made to reduce its electricity use. Furthermore, KCl mining wastes have received increasing attention because they can be transformed into value-added resources. This work studies the influence of using different salt sources on the environmental sustainability of the chlor-alkali industry to identify further improvement opportunities. Rock salt, solar salt, KCl waste salt, vacuum salt and solution-mined salt were studied. Membrane cells in both bipolar and monopolar configurations were studied and compared to the emergent oxygen-depolarised cathode (ODC) technology. Life cycle assessment was applied to estimate the cradle-to-gate environmental impacts. The natural resource (NR) requirements and the environmental burdens (EBs) to the air and water environments were assessed. The total NR and EB requirements were reduced by 20% when vacuum salt was replaced with KCl. Moreover, the environmental impacts estimated for the monopolar membrane using KCl were comparable to those generated for the bipolar membrane using VS. The difference between the monopolar and bipolar scenarios (17%) was slightly higher than that between the bipolar and ODC technologies (12%). This work demonstrates the importance of studying every life cycle stage in a chemical process and the environmental benefit of applying a circular economy, even in energy intensive industries such as the chlor-alkali industry.This work was funded by the Spanish Ministry of Economy and Competitiveness (MINECO), Project CTM2013-43539-R. The authors are grateful for this funding

Frequency-dependent signal transfer at the interface between electrogenic cells and nanocavity electrodes

We present a model to describe the response of chip-based nanocavity sensors during extracellular recording of action potentials. These sensors feature microelectrodes which are embedded in liquid-filled cavities. They can be used for the highly localized detection of electrical signals on a chip. We calculate the sensor's impedance and simulate the propagation of action potentials. Subsequently we apply our findings to analyze cell-chip coupling properties. The results are compared to experimental data obtained from cardiomyocyte-like cells. We show that both the impedance and the modeled action potentials fit the experimental data well. Furthermore, we find evidence for a large seal resistance of cardiomyocytes on nanocavity sensors compared to conventional planar recording systems

Nanocavity electrode array for recording from electrogenic cells

We present a new nanocavity device for highly localized on-chip recordings of action potentials from individual cells in a network. Microelectrode recordings have become the method of choice for recording extracellular action potentials from high density cultures or slices. Nevertheless, interfacing individual cells of a network with high resolution still remains challenging due to an insufficient coupling of the signal to small electrodes, exhibiting diameters below 10 µm. We show that this problem can be overcome by a new type of sensor that features an electrode, which is accessed via a small aperture and a nanosized cavity. Thus, the properties of large electrodes are combined with a high local resolution and a good seal resistance at the interface. Fabrication of the device can be performed with state-of-the-art clean room technology and sacrificial layer etching allowing integration of the devices into sensor arrays. We demonstrate the capability of such an array by recording the propagation of action potentials in a network of cardiomyocyte-like cells

Time-Resolved Mapping of Neurotransmitter Fluctuations by Arrays of Nanocavity Redox-Cycling Sensors

AbstractWe introduce a novel device for the spatiotemporal detection of neurotransmitters on-chip. Our device features an array of individually addressable nanocavity sensors that utilize redox-cycling for the localized electrochemical determination of neurotransmitter concentrations. This effect is based on rapid, repeated redox-reactions between two closely spaced electrodes and results in a high amplification of the electrochemical signal of individual molecules. Each sensor is equipped with two independently biased electrodes that are separated by an ∼65 nm wide cavity, thus enabling efficient redox-cycling amplification. The sensors feature entry ports in the micrometer regime and can be closely packed for the chemical mapping at high spatial resolutions.In this paper, we present the devices capabilities in neurotransmitter detection. The sensors are electrochemically characterized and their functionality is demonstrated by measuring localized dopamine fluctuations in a microfluidic channel