Metallic zinc is a promising anode candidate of aqueous zinc‐ion batteries owing to its high theoretical capacity and low redox potential. However, Zn anodes usually suffer from dendrite and side reactions, which will degrade their cycle stability and reversibility. Herein, we developed an in situ spontaneously reducing/assembling strategy to assemble a ultrathin and uniform MXene layer on the surface of Zn anodes. The MXene layer endows the Zn anode with a lower Zn nucleation energy barrier and a more uniformly distributed electric field through the favorable charge redistribution effect in comparison with pure Zn. Therefore, MXene‐integrated Zn anode exhibits obviously low voltage hysteresis and excellent cycling stability with dendrite‐free behaviors, ensuring the high capacity retention and low polarization potential in zinc‐ion batteries.
The excessive accumulation of iron in deep gray structures is an important pathological characteristic in patients with Alzheimer's disease (AD). Quantitative susceptibility mapping (QSM) is more specific than other imaging-based iron measurement modalities and allows noninvasive assessment of tissue magnetic susceptibility, which has been shown to correlate well with brain iron levels. This study aimed to investigate the correlations between the magnetic susceptibility values of deep gray matter nuclei and the cognitive functions assessed by mini-mental state examination (MMSE) and Montreal cognitive assessment (MoCA) in patients with mild and moderate AD. Thirty subjects with mild and moderate AD and 30 age- and sex-matched healthy controls were scanned with a 3.0 T magnetic resonance imaging (MRI) scanner. The magnetic susceptibilities of the regions of interest (ROIs), including caudate nucleus (Cd), putamen (Pt), globus pallidus (Gp), thalamus (Th), red nucleus (Rn), substantia nigra (Sn), and dentate nucleus (Dn), were quantified by QSM. We found that the susceptibility values of the bilateral Cd and Pt were significantly higher in AD patients than the controls ( P < 0.05). In contrast, bilateral Rn had significantly lower susceptibility values in AD than the controls. Regardless of gender and age, the increase of magnetic susceptibility in the left Cd was significantly correlated with the decrease of MMSE scores and MoCA scores ( P < 0.05). Our study indicated that magnetic susceptibility value of left Cd could be potentially used as a biomarker of disease severity in mild and moderate AD.
Implantable devices for the wireless modulation of neural tissue need to be designed for reliability, safety and reduced invasiveness. Here we report chronic electrical stimulation of the sciatic nerve in rats by an implanted organic electrolytic photocapacitor that transduces deep-red light into electrical signals. The photocapacitor relies on commercially available semiconducting non-toxic pigments and is integrated in a conformable 0.1-mm3 thin-film cuff. In freely moving rats, fixation of the cuff around the sciatic nerve, 10 mm below the surface of the skin, allowed stimulation (via 50-1,000-μs pulses of deep-red light at wavelengths of 638 nm or 660 nm) of the nerve for over 100 days. The robustness, biocompatibility, low volume and high-performance characteristics of organic electrolytic photocapacitors may facilitate the wireless chronic stimulation of peripheral nerves. Introduction Implantable neural interfaces are at the heart of bioelectronic medicine, a growing field which aims to provide electrical solutions to medical problems 1-3 . Direct electrical actuation of the nervous system is utilized clinically in deep brain stimulation 4 , prosthetic retina implants 5 , vagus nerve stimulation for treatment of epilepsy 6 and other disorders 7,8 , as well as in numerous other applications. Meanwhile, the list of emerging technologies at a preclinical phase is constantly growing 9,10 . Several fundamental engineering hurdles need to be overcome to facilitate widespread implementation of bioelectronic devices and ensure optimal clinical outcomes 11,12 . A key challenge is to improve long-term powering and miniaturization of implantable devices, motivating exploration of methods to wirelessly actuate and control implants from outside of the body. The most common approaches involve radio frequency (RF) power transmission or electromagnetic induction 13 . Although
The self‐assembly of large‐area MXene films is the main step to realize their applications in various energy storage devices. However, the scalable self‐assembly of flexible thin MXene films with high conductivity as well as excellent mechanical and electrochemical properties is still a challenge. Herein, a synchronous reduction and self‐assembly strategy to fabricate flexible MXene films is developed, where MXene films are synchronously reduced and self‐assembled on the Zn foil surface. Furthermore, the self‐assembly of MXene films can be scaled up by controlling the area of Zn substrates. By adjusting the patterns of Zn substrates, the interdigital MXene patterns can also be obtained via a selectively reducing/assembling process. The resultant MXene films demonstrate high electrical conductivity, large specific surface area, and excellent mechanical properties. Thus they can serve as the electrodes of flexible supercapacitor devices directly. As a proof of concept, flexible sandwich and microsized supercapacitors are designed based on the above MXene film electrodes. Both sandwich and microsized supercapacitors display stable electrochemical performance under various bending states. This study provides a route to achieve large‐area MXene‐based films or microsized structures for applications in the field of energy storage.
The
recent boom in flexible and wearable electronic devices has
increased the demand for flexible energy storage devices. The flexible
lithium-sulfur (Li-S) battery is considered to be a promising candidate
due to its high energy density and low cost. Herein, a flexible Li-S
battery was fabricated based on an all-in-one integrated configuration,
where a multiwalled carbon nanotubes/sulfur (MWCNTs/S) cathode, MWCNTs/manganese
dioxide (MnO2) interlayer, polypropylene (PP) separator,
and Li anode were integrated together by combining blade coating with
vacuum evaporation methods. Each component of the all-in-one structure
can be seamlessly connected with the neighboring layers. Such an optimal
interfacial connection can effectively enhance electron- and/or load-transfer
capacity by avoiding the relative displacement or detachment between
two neighboring components at bending strain. Therefore, the flexible
all-in-one Li-S batteries display fast electrochemical kinetics and
have stable electrochemical performance under different bending states.
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