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1. Fine-tuning Multimodal Large Language Models for Product Bundling

Author

Liu, Xiaohao, Wu, Jie, Tao, Zhulin, Ma, Yunshan, Wei, Yinwei, and Chua, Tat-seng

Subjects
Computer Science - Information Retrieval
Abstract

Recent advances in product bundling have leveraged multimodal information through sophisticated encoders, but remain constrained by limited semantic understanding and a narrow scope of knowledge. Therefore, some attempts employ In-context Learning (ICL) to explore the potential of large language models (LLMs) for their extensive knowledge and complex reasoning abilities. However, these efforts are inadequate in understanding mulitmodal data and exploiting LLMs' knowledge for product bundling. To bridge the gap, we introduce Bundle-MLLM, a novel framework that fine-tunes LLMs through a hybrid item tokenization approach within a well-designed optimization strategy. Specifically, we integrate textual, media, and relational data into a unified tokenization, introducing a soft separation token to distinguish between textual and non-textual tokens. Additionally, a streamlined yet powerful multimodal fusion module is employed to embed all non-textual features into a single, informative token, significantly boosting efficiency. To tailor product bundling tasks for LLMs, we reformulate the task as a multiple-choice question with candidate items as options. We further propose a progressive optimization strategy that fine-tunes LLMs for disentangled objectives: 1) learning bundle patterns and 2) enhancing multimodal semantic understanding specific to product bundling. Extensive experiments on four datasets across two domains demonstrate that our approach outperforms a range of state-of-the-art (SOTA) methods., Comment: Accepted by KDD 2025

Published
2024

2. LARP: Language Audio Relational Pre-training for Cold-Start Playlist Continuation

Author

Salganik, Rebecca, Liu, Xiaohao, Ma, Yunshan, Kang, Jian, and Chua, Tat-Seng

Subjects
Computer Science - Information Retrieval, Computer Science - Sound, Electrical Engineering and Systems Science - Audio and Speech Processing
Abstract

As online music consumption increasingly shifts towards playlist-based listening, the task of playlist continuation, in which an algorithm suggests songs to extend a playlist in a personalized and musically cohesive manner, has become vital to the success of music streaming. Currently, many existing playlist continuation approaches rely on collaborative filtering methods to perform recommendation. However, such methods will struggle to recommend songs that lack interaction data, an issue known as the cold-start problem. Current approaches to this challenge design complex mechanisms for extracting relational signals from sparse collaborative data and integrating them into content representations. However, these approaches leave content representation learning out of scope and utilize frozen, pre-trained content models that may not be aligned with the distribution or format of a specific musical setting. Furthermore, even the musical state-of-the-art content modules are either (1) incompatible with the cold-start setting or (2) unable to effectively integrate cross-modal and relational signals. In this paper, we introduce LARP, a multi-modal cold-start playlist continuation model, to effectively overcome these limitations. LARP is a three-stage contrastive learning framework that integrates both multi-modal and relational signals into its learned representations. Our framework uses increasing stages of task-specific abstraction: within-track (language-audio) contrastive loss, track-track contrastive loss, and track-playlist contrastive loss. Experimental results on two publicly available datasets demonstrate the efficacy of LARP over uni-modal and multi-modal models for playlist continuation in a cold-start setting. Code and dataset are released at: https://github.com/Rsalganik1123/LARP.

Published
2024

3. rFaceNet: An End-to-End Network for Enhanced Physiological Signal Extraction through Identity-Specific Facial Contours

Author

Zhu, Dali, Zhang, Wenli, Zeng, Hualin, Liu, Xiaohao, Yang, Long, and Zheng, Jiaqi

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

Remote photoplethysmography (rPPG) technique extracts blood volume pulse (BVP) signals from subtle pixel changes in video frames. This study introduces rFaceNet, an advanced rPPG method that enhances the extraction of facial BVP signals with a focus on facial contours. rFaceNet integrates identity-specific facial contour information and eliminates redundant data. It efficiently extracts facial contours from temporally normalized frame inputs through a Temporal Compressor Unit (TCU) and steers the model focus to relevant facial regions by using the Cross-Task Feature Combiner (CTFC). Through elaborate training, the quality and interpretability of facial physiological signals extracted by rFaceNet are greatly improved compared to previous methods. Moreover, our novel approach demonstrates superior performance than SOTA methods in various heart rate estimation benchmarks., Comment: under-review

Published
2024

4. ToDA: Target-oriented Diffusion Attacker against Recommendation System

Author

Liu, Xiaohao, Tao, Zhulin, Jiang, Ting, Chang, He, Ma, Yunshan, Wei, Yinwei, and Wang, Xiang

Subjects
Computer Science - Cryptography and Security
Abstract

Recommendation systems (RS) have become indispensable tools for web services to address information overload, thus enhancing user experiences and bolstering platforms' revenues. However, with their increasing ubiquity, security concerns have also emerged. As the public accessibility of RS, they are susceptible to specific malicious attacks where adversaries can manipulate user profiles, leading to biased recommendations. Recent research often integrates additional modules using generative models to craft these deceptive user profiles, ensuring them are imperceptible while causing the intended harm. Albeit their efficacy, these models face challenges of unstable training and the exploration-exploitation dilemma, which can lead to suboptimal results. In this paper, we pioneer to investigate the potential of diffusion models (DMs), for shilling attacks. Specifically, we propose a novel Target-oriented Diffusion Attack model (ToDA). It incorporates a pre-trained autoencoder that transforms user profiles into a high dimensional space, paired with a Latent Diffusion Attacker (LDA)-the core component of ToDA. LDA introduces noise into the profiles within this latent space, adeptly steering the approximation towards targeted items through cross-attention mechanisms. The global horizon, implemented by a bipartite graph, is involved in LDA and derived from the encoded user profile feature. This makes LDA possible to extend the generation outwards the on-processing user feature itself, and bridges the gap between diffused user features and target item features. Extensive experiments compared to several SOTA baselines demonstrate ToDA's effectiveness. Specific studies exploit the elaborative design of ToDA and underscore the potency of advanced generative models in such contexts., Comment: under-review

Published
2024

5. Leveraging Multimodal Features and Item-level User Feedback for Bundle Construction

Author

Ma, Yunshan, Liu, Xiaohao, Wei, Yinwei, Tao, Zhulin, Wang, Xiang, and Chua, Tat-Seng

Subjects
Computer Science - Information Retrieval, Computer Science - Multimedia, H.3.0
Abstract

Automatic bundle construction is a crucial prerequisite step in various bundle-aware online services. Previous approaches are mostly designed to model the bundling strategy of existing bundles. However, it is hard to acquire large-scale well-curated bundle dataset, especially for those platforms that have not offered bundle services before. Even for platforms with mature bundle services, there are still many items that are included in few or even zero bundles, which give rise to sparsity and cold-start challenges in the bundle construction models. To tackle these issues, we target at leveraging multimodal features, item-level user feedback signals, and the bundle composition information, to achieve a comprehensive formulation of bundle construction. Nevertheless, such formulation poses two new technical challenges: 1) how to learn effective representations by optimally unifying multiple features, and 2) how to address the problems of modality missing, noise, and sparsity problems induced by the incomplete query bundles. In this work, to address these technical challenges, we propose a Contrastive Learning-enhanced Hierarchical Encoder method (CLHE). Specifically, we use self-attention modules to combine the multimodal and multi-item features, and then leverage both item- and bundle-level contrastive learning to enhance the representation learning, thus to counter the modality missing, noise, and sparsity problems. Extensive experiments on four datasets in two application domains demonstrate that our method outperforms a list of SOTA methods. The code and dataset are available at https://github.com/Xiaohao-Liu/CLHE.

Published
2023

7. Pest-YOLO: A Lightweight Pest Detection Model Based on Multi-level Feature Fusion

Author

Zhu, Xiaoyue, Jia, Bing, Huang, Baoqi, Li, Haodong, Liu, Xiaohao, Seah, Winston K. G., Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Huang, De-Shuang, editor, Zhang, Chuanlei, editor, and Chen, Wei, editor

Published
2024
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22. Research progress on the tunnel technique for root coverage

Author

XIE Chengjie, LIU Xiaohao, CHEN Jie, WENG Jingxin, and CHEN Xiaochuan

Subjects
gingival recession ,, root coverage surgery ,, tunnel technique ,, coronally advanced flap ,, connective tissue ,, graft ,, modification technique ,, minimally invasive ,, esthetic ,, periodontal plastic surgery,, Medicine
Abstract

Gingival recessions (GRs) result in root hypersensitivity, root surface caries, and esthetic problems. Various root coverage surgeries are being developed for periodontal plastic therapy. The tunnel technique (TUN) is one of the most widely applied surgeries due to its features of being minimally invasive, practical, excellent outcomes and long-term stability; however, there are still some limitations of this technique. The history and evolution from the envelope flap to TUN, including its efficiency when compared with coronally advanced flaps with a connective tissue graft (CTG), are reviewed in this paper. The limitations of TUN are discussed in consideration of our clinical experience; for example, there is high technique sensitivity when TUN is applied in GR>5 mm because of the great difficulty in covering the grafts. The advantages of surgical access, including vertical incisions in the vestibule, “W” type and pinhole access, are discussed for different situations. Mattress sutures and sling sutures in a single tooth or multiple teeth are applied in TUN. The different types of grafts, such as CTG, platelet-rich plasma, articular dermal matrix and xenogeneic collagen matrix, are described. Mechanical, chemical and biological conditioning of the root surface are recommended during surgery. Protecting the surgical area and taking antibiotics postoperatively are also very important. Finally, the modifications when TUN is applied with other kinds of techniques are discussed, including lateral closed TUN, laterally positioned flaps, double papilla flaps and frenuloplasty. Minimally invasive, esthetic, long-term stability and simplified techniques are the development trends of TUN in the future.

Published
2023
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32. Entropy‐Assisted Anion‐Reinforced Solvation Structure for Fast‐Charging Sodium‐Ion Full Batteries.

Author

Zhou, Xunzhu, Chen, Xiaomin, Kuang, Wenxi, Zhu, Wenqing, Zhang, Xiaosa, Liu, Xiaohao, Wu, Xingqiao, Zhang, Longhai, Zhang, Chaofeng, Li, Lin, Wang, Jiazhao, and Chou, Shu‐Lei

Subjects
CONDUCTIVITY of electrolytes, IONIC conductivity, IONIC structure, ION transport (Biology), FAST ions
Abstract

Anion‐reinforced solvation structure favors the formation of inorganic‐rich robust electrode‐electrolyte interface, which endows fast ion transport and high strength modulus to enable improved electrochemical performance. However, such a unique solvation structure inevitably injures the ionic conductivity of electrolytes and limits the fast‐charging performance. Herein, a trade‐off in tuning anion‐reinforced solvation structure and high ionic conductivity is realized by the entropy‐assisted hybrid ester‐ether electrolyte. Anion‐reinforced solvation sheath with more anions occupying the inner Na+ shell is constructed by introducing the weakly coordinated ether tetrahydrofuran into the commonly used ester‐based electrolyte, which merits the accelerated desolvation energy and gradient inorganic‐rich electrode‐electrolyte interface. The improved ionic conductivity is attributed to the weakly diverse solvation structures induced by entropy effect. These enable the enhanced rate performance and cycling stability of Prussian blue||hard carbon full cells with high electrode mass loading. More importantly, the practical application of the designed electrolyte was further demonstrated by industry‐level 18650 cylindrical cells. [ABSTRACT FROM AUTHOR]

Published
2024
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33. Synthesis of folic acid, histidine, and serine-functionalized and boron and phosphorus-doped graphene quantum dots with excellent yellow luminescence behavior in aqueous/solid states and their use for the fluorescence detection of Fe2+ in urine

Author

Ruiyi, Li, Xie, Qingqing, Wang, Ye, Li, Zaijun, and Liu, Xiaohao

Subjects
QUANTUM dots, FLUORESCENCE yield, LUMINESCENCE, FLUORESCENCE, DOPING agents (Chemistry), FOLIC acid
Abstract

Low luminous efficiency at visible light excitation restricts many applications of graphene quantum dots in bioanalysis, bioimaging, and light-emitting diodes. Herein, we report the synthesis of folic acid, histidine, and serine-functionalized and boron and phosphorus-doped graphene quantum dots (FHS-GQD-B/P) using a one-step thermal treatment. The resulting FHS-GQD-B/P consists of tiny graphene sheets with an average size of 4.6 ± 0.28 nm. The synergy of multiple functional groups and multiple heteroatoms achieved excellent yellow luminescence behavior in the aqueous state and in the solid state. FHS-GQD-B/P can produce the strongest yellow fluorescence upon excitation with visible light at 490 nm. The fluorescence quantum yield reached 60.2%, which is higher than that of the other graphene quantum dots emitting yellow light. The fluorescence emission wavelength is independent of excitation wavelength, FHS-GQD-B/P concentration, and medium acidity. Interestingly, the yellow fluorescence can be quenched by Fe2+ in the presence of o-phenanthroline. Based on this, a method was developed for the fluorescence detection of Fe2+. The fluorescence intensity linearly decreases with the increase of Fe2+ concentration in the range of 0.01–50 μM with a detection limit of 0.0042 μM and a signal-to-noise ratio of 3. The as-proposed analytical method was satisfactorily applied in the fluorescence detection of Fe2+ in urine. [ABSTRACT FROM AUTHOR]

Published
2024
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34. Sodium Difluoro(oxalato)borate Additive‐Induced Robust SEI and CEI Layers Enable Dendrite‐Free and Long‐Cycling Sodium‐Ion Batteries.

Author

Liu, Xiaohao, Zhao, Jiahua, Dong, Huanhuan, Zhang, Lingling, Zhang, Hang, Gao, Yun, Zhou, Xunzhu, Zhang, Longhai, Li, Li, Liu, Yang, Chou, Shuchun, Lai, Weihong, Zhang, Chaofeng, and Chou, Shulei

Subjects
*TRANSITION metal ions, *PRUSSIAN blue, *DENDRITIC crystals, *ENERGY storage, *DENDRITES
Abstract

Sodium‐ion batteries (SIBs) are a promising candidate for large‐scale energy storage due to the low cost and abundant sodium resources. However, the formation of sodium dendrites on the surface of hard carbon (HC) anodes is the most intractable challenge for full cells during charging, leading to severe performance degradation and safety hazards. Here, a robust additive‐induced borate and fluoride‐rich interphase is constructed by introducing sodium difluoro(oxalato)borate (NaDFOB) as additive in the ether‐based electrolyte to relieve the performance deterioration for SIBs. NaDFOB can participate in the passivation process of electrolyte‐electrode interfaces through preferential oxidation and reduction of DFOB− to effectively restrain the growth of sodium dendrites. Moreover, the electrolyte decomposition and dissolution of transition metal ions are effectively inhibited. Benefiting from that, FeMn‐based Prussian blue (FeMnHCF) || HC full cell with a negative/positive capacity ratio (N/P ratio) of 1.09 displays a capacity retention of 82.1%, especially with a low N/P ratio of 0.96 the cell still demonstrates a stable Coulombic efficiency of over 99.9% after 500 cycles via using NaDFOB as additive. As a practical demonstration, the designed 18650 full cells display enhanced cycling stability with NaDFOB additive. The findings provide insights into the additive‐induced inorganic‐rich interfacial layers for dendrite‐free SIBs. [ABSTRACT FROM AUTHOR]

Published
2024
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42. Effect of Rh loading on the selectivity to methanol and ethanol in the hydrogenation of CO2over the Rh/CeO2catalyst

Author

ZHENG, Ke, LIU, Bing, XU, Yuebing, and LIU, Xiaohao

Abstract

The capture and hydrogenation of CO2into high-value chemicals such as alcohols is one of the important ways to reduce CO2emission and achieve carbon resource recycling. In this work, the catalytic performance of Rh/CeO2catalyst in the CO2hydrogenation was investigated; with the help of various characterization methods including XRD, Raman, H2-TPR, CO2-TPD, CO-DRIFTS and XPS, the influence of Rh loading (0.1%–2.0%) on the catalytic activity of Rh/CeO2and product selectivity in the CO2hydrogenation was revealed. The results indicate that for the hydrogenation of CO2at 250 °C and 3.0 MPa over the Rh/CeO2catalysts, ethanol is the major product at a low Rh loading of 0.1%. With the increase of Rh loading, the conversion of CO2increases, but accompanied by a decrease in the selectivity to ethanol; when the Rh loading reaches 2.0%, the main product turns to be methanol. It seems that the difference of various Rh/CeO2catalysts with different Rh loadings in the product selectivity for the CO2hydrogenation is ascribed to their difference in the structural and electronic properties of Rh; atomically dispersed Rh+species favor the stabilization of CO* and its subsequent C–C coupling with CH3* to form ethanol, whereas metallic Rh clusters facilitate the hydrogenation of CO* to produce methanol.

Published
2024
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43. Study on reaction performance in methane dry reforming over Ni-based catalysts regulated by support morphologies.

Author

LI Zhenwei, LI Yufeng, CHEN Jie, XU Yuebing, LIU Bing, and LIU Xiaohao

Subjects
X-ray diffraction, GREENHOUSE gases, SURFACE area, METALS, CATALYSTS, NICKEL catalysts
Abstract

The methane dry reforming (DRM) reaction is of great significance for the co-conversion and utilization of greenhouse gases CO2 and CH4. However, this reaction faces the crucial problem of catalyst deactivation caused by carbon deposition. The influence of support morphologies on the reaction performance in DRM over Ni-based catalysts was investigated by preparing flower-shaped, granular and sheet-like MgO supported catalysts. The influence mechanisms were clarified by various characterizations such as XRD, SEM, H2-TPR, CO2-TPD and TG. The results show that under the temperature of 800 °C and space velocity of 54000 mL/(g-h), the average CO2 and CH4 conversion rates of Ni-based catalysts supported on flower-shaped MgO reach 90.2% and 82.3%, respectively, with the average n(H2)/n(CO) of 0.93 after 50 h reaction. Compared with Ni-based catalysts supported on granular and sheet-like MgO, the Ni-based catalyst supported on flower-shaped MgO exhibits higher activity, stability and anti-carbon deposition ability. This is because the flower-shaped MgO has a higher specific surface area favorable for the dispersion of active metals, and there are more alkaline sites on the surface of flower-shaped MgO, which contribute to the adsorption and activation of CO2, enhance the anti-carbon deposition ability of catalysts and improve the activity and stability of DRM reaction. [ABSTRACT FROM AUTHOR]

Published
2024

44. Theoretical calculation study on effects of H coverage on CO activation in Fischer-Tropsch synthesis catalysts.

Author

WANG Yuxin, LIU Bing, and LIU Xiaohao

Subjects
ACTIVATION energy, GIBBS' free energy, CATALYST synthesis, HYDROGEN as fuel, SURFACE cleaning
Abstract

Fe-based and Co-based catalysts are the most ideal Fischer-Tropsch synthesis catalysts. With the rapid development of computer simulation technology in the field of catalysis, it is possible to deeply understand the microscopic reaction mechanism on the surface of Fe-based and Co-based catalysts. Theoretical calculation method was used to study the effects of surface structures of Fe-based (reaction conditions: temperature 320 °C, pressure 1 MPa and n(H2):n(CO) = 1:1) and Co-based (reaction conditions: temperature 240 °C, pressure 1 MPa and n(H2):n(CO) = 2:1) Fischer-Tropsch synthesis catalysts with different H coverages on the activation and dissociation of CO. The thermodynamically preferred H-covered surface models of Fe-based and Co-based Fischer-Tropsch synthesis catalysts were determined through the linear relationships between the hydrogen chemical potential and the Gibbs free energy of hydrogen adsorption, which is the X-Fe5C2(510) surface with H coverage of 11/42 and HCP Co(0001) surface with H coverage of 24/36, respectively. The CO dissociation mechanism and corresponding reaction energy barriers on the clean surface and the H-covered surface of catalysts were studied, and it is found that H coverage can change the reaction pathways of CO dissociation and increase the dissociation energy barrier. Compared with the clean surfaces of X-Fe5C2(510) and HCP Co(0001), the dissociation energy barriers of CO on H-covered X-Fe5C2(510) and HCP Co(0001) surfaces increase by 5.4% and 20.3%, respectively. The origin reasons for the effects of H coverage on CO activation and dissociation were explained by calculating the density of states and crystal orbitals Hamiltonian population. [ABSTRACT FROM AUTHOR]

Published
2024

45. Computational study of momentum interactions between fluid and a static particle under the impact of anisotropic Stefan flow.

Author

Qi, Fenglei, Wang, Shaolun, Xu, Yuefeng, Diao, Rui, Liu, Xiaohao, Yan, Hao, and Ma, Peiyong

Subjects
DRAG coefficient, DRAG reduction, GRANULAR flow, COMPUTER simulation, FLUIDS
Abstract

The microscale gas–particle interaction is the determining process for the macroscopic flow behaviors of gas–particle systems. Anisotropic Stefan flow is often manifested at the surface of the biomass particle when thermally decomposed. However, the influence of the anisotropic Stefan flow on the gas–particle interactions is not well understood. To this end, particle-resolved direct numerical simulations were carried out in this research to explore the momentum interactions between the gas flow and a static particle emitting mass flux at its surface. A signed distance function based immersed boundary method is first extended to account for the Stefan flow at the gas–particle interface and successfully validated by comparing with literature results in the case of no Stefan flow or uniform Stefan flow. It is found that the presence of the outward uniform Stefan flow leads to an expanded wake formation and the intensity of the vortex (Re ≥ 40) is enhanced as result of the Stefan flow. Subject to the impact of anisotropic Stefan flow parallel to the main flow, the low-speed region in the front and rear of the particle is reduced when the Stefan flow goes inwards, resulting in the increase in the drag coefficient. As the Stefan flow is outward, the low-speed region in the front of the particle is pushed forward by the emitting gas and the velocity magnitude in the wake region is increased, which behaves like an enlargement of the gas cushion and leads to a significant reduction of the drag coefficient comparing with a uniform Stefan flow. In contrast, the impact of anisotropic Stefan flow with the direction perpendicular to the main flow on the fluid–particle drag interaction is less significant due to the fact that the flow structure in the front and rear regions is not significantly disturbed. [ABSTRACT FROM AUTHOR]

Published
2024
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46. Graphene quantum dot surface ligand and Co and Pt double-doping-engineered Co/Co3O4 nanozyme displaying superior performance to horseradish peroxidase and choline oxidase for the efficient degradation of rhodamine B without an activator

Author

Li, Nana, Li, Ruiyi, Li, Zaijun, and Liu, Xiaohao

Subjects
HORSERADISH peroxidase, QUANTUM dots, GRAPHENE, CHOLINE, CATALYTIC activity, COORDINATION polymers
Abstract

Nanozymes show great potential in organic degradation because of their good stability and low cost. However, their poor catalytic activity and functional diversity restrict their practical applications. The present study reports the synthesis of a Pt/Co/Co3O4/EW-GQD nanozyme via the coordination of Co2+ and Pt4+ with a glutamate and tryptophan-functionalized graphene quantum dot (EW-GQD) and subsequent thermal reduction and part oxidation. The graphene surface ligand engineering creates a reactive microenvironment similar to natural enzymes, facilitating a high-speed electron-transfer process from Co3O4 to graphene and strong adsorption capacity toward rhodamine B. The Co and Pt double doping narrows the bandgap and leads to an improved electronic conductivity. The Pt/Co/Co3O4/EW-GQD nanozyme exhibited a peroxidase-like specific activity of 1662.67 U mg−1 and oxidase-like specific activity of 293.45 U mg−1, which exceed by 3.2-fold that of horseradish peroxidase and by 15.6-fold that of choline oxidase. This enabled a 3.6-fold increase in the degradation efficiency of rhodamine B without the need for an activator. The high catalytic activity was mainly attributed to the perfect combination of the graphene surface ligand and Co and Pt double engineering, which produced multiple active sites such as Co3+/Co2+, Pt4+/Pt2+, and pyrrolic N/pyridinic N and multiple active species such as 1O2, ˙O2, and ˙OH. This work introduces a novel way for the design and synthesis of nanozymes with excellent catalytic activity and multifunctional performance. [ABSTRACT FROM AUTHOR]

Published
2024
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47. Mild and scalable synthesis of a high performance CrFeCoNiRu0.05 high entropy nano-alloy/carbon electrocatalyst for efficient urea production with a chelate-based ionic liquid.

Author

Zhang Qingqing, Ruiyi Li, Zaijun Li, Yang Yongqiang, and Liu Xiaohao

Subjects
IONIC liquids, COUPLING reactions (Chemistry), UREA, ENTROPY, SALICYLIC acid, ELECTROLYTIC reduction, METHANATION
Abstract

High-entropy alloys show broad application prospects in electrocatalysis due to their high catalytic activity, conductivity and structural stability. However, achieving their mild and scalable synthesis still remains a great challenge. This paper reports a strategy for the synthesis of CrFeCoNiRu0.5 high entropy nano-alloy/carbon (termed as CrFeCoNiRu0.5-HENA/C) using a chelate-based ionic liquid. Cr(III), Fe(III), Co(II), Ni(II) and Ru(III) were coordinated with salicylic acid ionic liquid to form a viscous metal complex solution, followed by low temperature carbonization and subsequent high temperature annealing. The resulting CrFeCoNiRu0.5- HENA/C consists of a three-dimensional carbon framework and CrFeCoNiRu0.5-HENA nanocrystal. The carbon framework offers high ion/electron conductivity and good affinity with NO3- and CO2 due to the presence of hydrophilic oxygen-containing groups and highly electronegative nitrogen atoms. The CrFeCo-NiRu0.5-HENA nanocrystal has a small size of 52.5 x 1.2 nm, good element homogeneity and high crystallinity. Such a unique structure improves the adsorption capacity towards NO3 - and CO2 and the electrocatalytic activity towards the C-N coupling reaction. The CrFeCoNiRu0.5-HENA/C electrocatalyst exhibits a high urea yield of 35.57 x 0.81 mmol gcatalyst -1 h-1 with a high faradaic efficiency of 21.02-0.77%, which is much better than that of multi-component nano-alloys from Cr, Fe, Co, Ni and Ru. This study also provides an approach for the construction of high-entropy nano-alloys in catalysis, sensing and energy storage and conversion. [ABSTRACT FROM AUTHOR]

Published
2024
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