Engineering electrocatalyst nanosurfaces to enrich the activity by inducing lattice strain

“…Strain effect has been actively studied to stimulate the inactive surfaces of various catalysts. [ 13 ] By modulating the atomic distances to generate lattice strain, the d‐band center will be shifted, which can optimize the chemisorption, and in turn improve the catalytic performance. [ 14 ] Structural defect is an important source of lattice strain, [ 13 ] and surface reconstruction has been commonly used to introduce structural defect, [ 15 ] especially in electrocatalysis.…”

Section: Introductionmentioning

confidence: 99%

“…[13] By modulating the atomic distances to generate lattice strain, the d-band center will be shifted, which can optimize the chemisorption, and in turn improve the catalytic performance. [14] Structural defect is an important source of lattice strain, [13] and surface reconstruction has been commonly used to introduce structural defect, [15] especially in electrocatalysis. However, the lattice strain of noble metal nanomaterials induced by surface reconstruction has rarely been studied.In this work, we introduced lattice tensile strain into Pd NSs by surface reconstruction for nanozyme-based catalytic therapy and dual phototherapy.…”

mentioning

confidence: 99%

Tensile‐Strained Palladium Nanosheets for Synthetic Catalytic Therapy and Phototherapy

et al. 2022

Advanced Materials

View full text Add to dashboard Cite

other functional materials for synergetic therapy is necessary. [4] It complicates the structure and preparation, leading to low reproducibility and reliability, and high side effects and costs. [5] To address this dilemma, developing monocomponent nanomaterials with multifunctionality for nanozyme-based synergetic therapy is of great importance, but challenging. [6] Palladium nanosheets (Pd NSs) are well-investigated photothermal therapy (PTT) agents owing to high stability, shape uniformity, and strong surface plasmon resonance in near-infrared (NIR) region. [7] Although Pd-based materials are superior catalysts in many fields, [8] the catalytic potential of Pd NSs has been underexplored for tumor treatment, such as photodynamic therapy (PDT) and nanozymebased catalytic therapy, because Pd NSs are mainly enclosed by inactive (111) facet, which is close packed and has the lowest surface free energy among all facets. [9] To realize catalytic capacities, other metals, such as gold and platinum, [10] or organic photosensitizers [11] had to be combined with Pd NSs. Very recently, we introduced 1D nanoholes with active (100) facets into Pd NSs. [12] This provided them with high NIR-light photocatalytic activity of activation O 2 to singlet oxygen ( 1 O 2 ) for PDT. However, the catalytic potential of the dominant (111) planes has still not been explored. Strain effect has been actively studied to stimulate the inactive surfaces of various catalysts. [13] By modulating the atomic distances to generate lattice strain, the d-band center will be shifted, which can optimize the chemisorption, and in turn improve the catalytic performance. [14] Structural defect is an important source of lattice strain, [13] and surface reconstruction has been commonly used to introduce structural defect, [15] especially in electrocatalysis. However, the lattice strain of noble metal nanomaterials induced by surface reconstruction has rarely been studied.In this work, we introduced lattice tensile strain into Pd NSs by surface reconstruction for nanozyme-based catalytic therapy and dual phototherapy. Surface reconstruction caused a large number of structural defects, leading to lattice tensile strain. It activated the inert (111) planes, affording the strained Pd NSs (SPd NSs) with high PDT performance. In addition, SPd NSs exhibited catalase (CAT)-like activity for O 2 production from H 2 O 2 in TME, further strengthening the O 2 -dependent PDT. Moreover, lattice tensile strain was favorable for ROS generation by activation of H 2 O 2 , boosting the peroxidase (POD)-like activity. Tensile strain promoting the photodynamic and enzyme-like Palladium nanosheets (Pd NSs) are well-investigated photothermal therapy agents, but their catalytic potential for tumor therapy has been underexplored owing to the inactive dominant (111) facets. Herein, lattice tensile strain is introduced by surface reconstruction to activate the inert surface, endowing the strained Pd NSs (SPd NSs) with photodynamic, catalase-like, and peroxidase-like properties. Ten...

show abstract

“…Generally, the commonality of these approaches is to change the electronic structure of the atomic surface by adjusting or controlling the physical and chemical state of the catalyst surface, so as to simultaneously optimize the binding strength between different reaction intermediates (e.g., *H, *O, *OOH, and *OH) and active sites. Analogously, surface strain engineering has emerged as one of the most promising ways in precisely modulating the electronic configuration and altering binding energies toward adsorbates by the atomic‐scale structural deformation effects (lattice compressive or tensile strain) 15–26 . Recent studies have shown that the lattice strain can be maximized to tailor the d‐band orbital overlap and significantly alter the Gibbs adsorption/desorption free energy for reactive intermediates by modifying the distance between atoms, and thus efficiently stimulate the intrinsic activity of the catalyst in various electrochemical reactions (e.g., HER, OER, and ORR) 15–19,27–32 .…”

Section: Introductionmentioning

confidence: 99%

Activating ruthenium dioxide via compressive strain achieving efficient multifunctional electrocatalysis for Zn‐air batteries and overall water splitting

Qiu

Rao

Zheng

et al. 2022

InfoMat

View full text Add to dashboard Cite

Surface strain engineering is a promising strategy to design various electrocatalysts for sustainable energy storage and conversion. However, achieving the multifunctional activity of the catalyst via the adjustment of strain engineering remains a major challenge. Herein, an excellent trifunctional electrocatalyst (Ru/RuO 2 @NCS) is prepared by anchoring lattice mismatch strained core/shell Ru/RuO 2 nanocrystals on nitrogen-doped carbon nanosheets. Core/shell Ru/RuO 2 nanocrystals with ~5 atomic layers of RuO 2 shells eliminate the ligand effect and produce ~2% of the surface compressive strain, which can boost the trifunctional activity (oxygen evolution reaction [OER], oxygen reduction reaction [ORR], and hydrogen evolution reaction [HER]) of the catalyst. When equipped in rechargeable Zn-air batteries, the Ru/RuO 2 @NCS endows them with high power (137.1 mW cm À2 ) and energy (714.9 Wh kg Zn À1) density and excellent cycle stability.Moreover, the as-fabricated Zn-air batteries can drive a water splitting electrolyzer assembled with Ru/RuO 2 @NCS and achieve a current density of 10 mA cm À2 only requires a low potential ~1.51 V. Density functional theory calculations reveal that the compressive strained RuO 2 could reduce the reaction barrier and improve the binding of rate-determining intermediates (*OH, *O, *OOH, and *H), leading to the enhanced catalytic activity and stability. This work can provide a novel avenue for the rational design of multifunctional catalysts in future clean energy fields.

show abstract

Engineering electrocatalyst nanosurfaces to enrich the activity by inducing lattice strain

Abstract: Electrocatalysis undeniably offers noteworthy improvements to future energy conversion and storage technologies, such as fuel cells, water electrolyzers, and metal–air batteries. Molecular interaction between catalytic surfaces and chemical reactants produces...

Cited by 129 publications

References 174 publications

Design principles of noble metal-free electrocatalysts for hydrogen production in alkaline media: combining theory and experiment

Design principles of noble metal-free electrocatalysts for hydrogen production in alkaline media: combining theory and experiment

Tensile‐Strained Palladium Nanosheets for Synthetic Catalytic Therapy and Phototherapy

Activating ruthenium dioxide via compressive strain achieving efficient multifunctional electrocatalysis for Zn‐air batteries and overall water splitting

Contact Info

Product

Resources

About