Haiyin Gang scite author profile

Capacitive deionization technology for brackish water treatment has been widely studied but currently still suffers from relatively low efficiency. Therefore, a rational design of promising electrode materials has become an urgent task. In this study, a so-called pore-on-pore strategy was developed by chemical activation of the intrinsic porous renewable precursor to generate a micro–meso hierarchical porous carbon. The synergistic effect of the biocomponent and activation agent is the major mechanism for the high porosity. The synthetic carbon has a very high specific surface area (2147.43 m2 g–1). In addition, the carbon exhibits good performance in terms of electroadsorption, with adsorption capacities of 19.35 and 30.64 mg g–1 in solutions with initial concentrations of 500 and 1500 mg L–1 NaCl under 1.2 V applied voltage, respectively. A capacitance retention of 98.7% and charging efficiency of 98.3% were achieved after 100 uninterrupted charge and discharge cycles, indicating relatively good regeneration performance. This research provides a bright way to develop an excellent performance electrode from renewable resources for environmental applications.

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Carbon Nanoarchitectonics with Bi Nanoparticle Encapsulation for Improved Electrochemical Deionization Performance

Wang

Wei

et al. 2022

ACS Appl. Mater. Interfaces

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Electrochemical deionization (EDI) is hopefully the next generation of water treatment technology. Bismuth (Bi) is a promising anode material for EDI, due to its high capacity and selectivity toward Cl–, but the large volume expansion and severe pulverization aggressively attenuated the EDI cycling performance of Bi electrodes. Herein, carbon-layer-encapsulated nano-Bi composites (Bi@C) were prepared by a simple pyrolysis method using a Bi-based metal–organic framework as a precursor. Bi nanoparticles are uniformly coated within the carbon layer, in which the Bi–O–C bond enhances the interaction between Bi and C. Such a structure effectively relieves the stress caused by volume expansion by the encapsulation effect of the carbon layer. Moreover, the introduction of a carbon skeleton provides a conductive network. As a consequence, the Bi@C composite delivered excellent electrochemical performance with a capacity of 537.6 F g–1 at 1 mV s–1. The Cl– removal capacity was up to 133.5 mg g–1 at 20 mA g–1 in 500 mg L–1 NaCl solution. After 100 cycles, the Bi@C electrode still maintains 71.8% of its initial capacity, which is much higher than the 26.3% of the pure Bi electrode. This study provides a promising strategy for improving EDI electrode materials.

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Enhanced Pseudo-Capacitance Process in Nanoarchitectural Layered Double Hydroxide Nanoarrays Hollow Nanocages for Improved Capacitive Deionization Performance

Wei

Cao

Gang

et al. 2023

ACS Appl. Mater. Interfaces

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Layered double hydroxides (LDHs) are perceived as a hopeful capacitive deionization (CDI) faradic electrode for Cl– insertion due to its tunable composition, excellent anion exchange capacity, and fast redox activity. Nevertheless, the self-stacking and inferior electrical conductivity of the two-dimensional structure of LDH lead to unsatisfactory CDI performance. Herein, the three-dimensional (3D) hollow nanocage structure of CoNi-layered double hydroxide/carbon composites is well designed as a CDI anode by cation etching of the pre-carbonized ZIF-67 template. C/CoNi-LDH has a unique 3D hollow nanocage structure and abundant pore features, which can effectively suppress the self-stacking of LDH sheets and facilitate the transport of ions. Moreover, the introduced amorphous carbon layer can act as a conductive network. When employed as the CDI anode, C/CoNi-LDH exhibited a high Cl– removal capacity of 60.88 mg g–1 and a fast Cl– removal rate of 18.09 mg g–1 min–1 at 1.4 V in 1000 mg L–1 NaCl solution. The mechanism of the Cl– intercalation pseudo-capacitance reaction of C/CoNi-LDH is revealed by electrochemical kinetic analysis and ex situ characterization. This study provides vital guidance for the design of high-performance electrodes for CDI.

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Stability study of transition metal oxide electrode materials

Cao

Gang

et al. 2023

Journal of Power Sources

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Efficient Removal of Chlorine Ions by Ultrafine Fe₃C Nanoparticles Encapsulated in a Graphene/N-Doped Carbon Hybrid Electrode: Redox and Confinement Effect

Deng

Gang

Cao

et al. 2023

ACS Sustainable Chem. Eng.

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Developing a high-performance Cl-storage electrode is a crucial issue for capacitive deionization (CDI). Iron-/nitrogen-doped carbon hybrid composites with densely dispersed ultrafine Fe-based nanoparticles are promising candidates for Cl-storage electrodes, yet further improvement of Fe-based nanoparticles prone to agglomeration is strongly desired. Hereby, a hybrid electrode with ultrafine iron carbide nanoparticles encapsulated in graphene/chitosan-derived N-doped carbon (Fe 3 C@GNC) is successfully constructed via facile one-step pyrolysis of aerogel composites. The encapsulation effect of graphene can effectively confine Fe 3 C nanoparticles in the carbon matrix, enabling stable and dispersive ultrafine Fe 3 C nanoparticles, and chitosan also enables N-doping. Also, a satisfactory conductive system with synergistically long-and short-range conductive networks is successfully generated by the graphene/N-doped carbon matrix. The Fe 3 C@GNC electrode exhibits a typical pseudocapacitive behavior, with a specific capacitance of up to 305.33 F g −1 and a dominant capacitive contribution of up to 96%. As a Cl-storage electrode for CDI, it delivers a Cl − adsorption capacity as high as 82.08 mg g −1 with a retention rate of 74.2% for 150 cycles. Furthermore, it is revealed that the Cl − storage mechanism of Fe 3 C@ GNC is a pseudocapacitance effect induced by the reversible Fe 2+ /Fe 3+ redox couple, which can achieve fast reaction kinetics and structural stability in the CDI process.

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Haiyin Gang

Hierarchical Porous Carbon from the Synergistic “Pore-on-Pore” Strategy for Efficient Capacitive Deionization

Carbon Nanoarchitectonics with Bi Nanoparticle Encapsulation for Improved Electrochemical Deionization Performance

Enhanced Pseudo-Capacitance Process in Nanoarchitectural Layered Double Hydroxide Nanoarrays Hollow Nanocages for Improved Capacitive Deionization Performance

Stability study of transition metal oxide electrode materials

Efficient Removal of Chlorine Ions by Ultrafine Fe₃C Nanoparticles Encapsulated in a Graphene/N-Doped Carbon Hybrid Electrode: Redox and Confinement Effect

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Haiyin Gang

Hierarchical Porous Carbon from the Synergistic “Pore-on-Pore” Strategy for Efficient Capacitive Deionization

Carbon Nanoarchitectonics with Bi Nanoparticle Encapsulation for Improved Electrochemical Deionization Performance

Enhanced Pseudo-Capacitance Process in Nanoarchitectural Layered Double Hydroxide Nanoarrays Hollow Nanocages for Improved Capacitive Deionization Performance

Stability study of transition metal oxide electrode materials

Efficient Removal of Chlorine Ions by Ultrafine Fe3C Nanoparticles Encapsulated in a Graphene/N-Doped Carbon Hybrid Electrode: Redox and Confinement Effect

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Product

Resources

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Efficient Removal of Chlorine Ions by Ultrafine Fe₃C Nanoparticles Encapsulated in a Graphene/N-Doped Carbon Hybrid Electrode: Redox and Confinement Effect