MXene-Based Bilayer Structures with Multiresponsive Actuating and Sensing Multifunctions

We successfully constructed an ultrathin Ti 3 C 2 T x supported Pt nanocluster catalyst for highly selective and efficient hydrogenation of pchloronitrobenzene (p-CNB) to p-chloroaniline (p-CAN) under mild conditions (30 °C, 0.1 MPa H 2 ). The Pt/Ti 3 C 2 T x catalyst displayed a very high conversion (>99%) and selectivity (>99%). In addition, a higher reaction rate (41 mol h −1 g −1 ) was obtained in comparison with the previously reported catalysts. The excellent catalytic activity of Pt/Ti 3 C 2 T x was attributed to the strong metal−support interactions between Pt nanoclusters and the support, in which the electrons were transferred from Ti 3 C 2 T x to Pt sites, affording a high electron density of Pt active sites. Moreover, the electrostatic repulsion between C−Cl moiety and Pt sites inhibited the dechlorination process. In addition, the Pt/Ti 3 C 2 T x catalyst also exhibited excellent performance in substrate scope (reducible heterocyclics such as pyridine and phthalimide), stability (10th cycles, conversion >99% and selectivity 98%), and gramscale reaction (99% yield, 1.89 g). This work will promote the research in constructing efficient and highly selective noble metalbased catalysts for hydrogenation of halogenated nitroarenes.

Section: Introductionmentioning

confidence: 99%

Pt Nanoclusters Supported on Ti₃C₂T_x Nanosheets for the Selective Hydrogenation of Halogenated Nitroarenes under Mild Conditions

Li,

Gao,

et al. 2024

Soybean Root-Inspired SWCNT/Ag@Au Composite Electrode for Ionic Polymer–Metal Composite Actuators

Niu,

Wang,

et al. 2024

Ionic polymer−metal composites (IPMCs), as innovative soft smart polymers, can effectively convert electrical energy into mechanical energy through electrochemically induced ion migration, demonstrating significant potential in soft intelligent robotics. As the actuation characteristics of IPMC actuators are largely determined by the electrochemical kinetics within the electrodes, it is highly desired to fabricate tailored electrodes with excellent electrical conductivity and superior electrochemical characteristics to develop high-performance IPMC actuators. Taking inspiration from the distinctive structure of soybean roots, we propose the concept of developing a soybean root-style composite electrode consisting of single-walled carbon nanotubes, silver nanoparticles, and gold nanoparticles for IPMCs using a combination of spray coating and electroplating technologies. The developed electrodes have a unique hierarchical structure, low surface resistance (2.80 Ω/sq), and greatly enhanced electrochemical characteristics because of the redox reactions of silver nanoparticles during the actuation process, which would facilitate the ion migration and storage in actuation. Accordingly, the resulting IPMC actuator outputs excellent electromechanical work under 2 V voltage, including large peak-to-peak deformation (displacement 14.91 mm, strain 0.94%), high deformation rate (1.07 mm/s), wide frequency response (0.01−10 Hz), and high generated stress (3.67 MPa). The IPMC actuators can be used to construct flexible artificial fingers, enabling efficient grasping and transport of delicate flowers without causing any damage to their surfaces. This study provides insight into the design and optimization of composite electrode materials for advanced IPMC actuators with improved functional capabilities in various applications.

Wax-Coated Graphene Oxide Films as Moisture-Responsive Actuators

Fu,

Song,

Wang

et al. 2024

Recently, soft actuators with the capabilities of stimuli response have attracted great attention and shown potential application prospects in soft robots. The critical factor of soft actuators to realize practical applications is the programmable shape deformations. However, it remains a challenge to develop a simple and versatile method to design a soft actuator with programmable deformations. Herein, we report a programmable graphene oxide (GO)/wax moisture-responsive actuator through water-shaping and heat-welding methods. Diverse actuators with different initial shapes can be achieved by the water-shaping method, which provides the possibility for preparing actuators with various desired shapes. Additionally, more complex 3D configurations of actuators can be programmed by the heat-welding method. As proof-of-concept demonstrations, several soft robots, such as a bionic walking robot, a grasping robot, and a weight-bearing robot, are demonstrated. Certainly, the versatile and simple programming methods of soft actuators hold great potential for intelligent robotics.