One-step, template-free synthesis of highly porous nitrogen/sulfur-codoped carbons from a single protic salt and their application to CO<sub>2</sub> capture

Zhang, Shiguo; Li, Zhe; Ueno, Kazuhide; Tatara, Ryoichi; Dokko, Kaoru; Watanabe, Masayoshi

doi:10.1039/c5ta03575a

Cited by 34 publications

(20 citation statements)

References 84 publications

(194 reference statements)

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“…Elemental analyses were performed to access the element compositions of the carbon materials in this work, especially N content, which was beneficial to CO 2 capture. 47 − 49 As shown in Table 1 , a common tendency of the decreasing N content from 16.84 to 1.87 wt % with the increasing pyrolysis temperature for carbon samples NDPC-1- y was observed. Among them, the N content of NDPC-1-800 was much lower than that of NDC-800, mainly due to the utilization of hydrochloric acid when removing templates.…”

Section: Results and Discussionmentioning

confidence: 70%

Constructing Hierarchically Porous N-Doped Carbons Derived from Poly(ionic liquids) with the Multifunctional Fe-Based Template for CO₂ Adsorption

et al. 2021

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Nitrogen-doped hierarchical porous carbons with a rich pore structure were prepared via direct carbonization of the poly(ionic liquid) (PIL)/potassium ferricyanide compound. Thereinto, the bisvinylimidazolium-based PIL was a desirable carbon source, and potassium ferricyanide as a multifunctional Fe-based template, could not only serve as the pore-forming agent, including metallic components (Fe and Fe 3 C), potassium ions (etching carbon framework during carbonization), and gas generated during the pyrolysis process, but also introduce the N atoms to porous carbons, which were in favor of CO 2 capture. Moreover, the hierarchically porous carbon NDPC-1-800 (NDPC, nitrogen-doped porous carbon) had taken advantage of the highest specific surface area, exhibiting an excellent CO 2 adsorption capacity and selectivity compared with NDC-800 (NDC, nitrogen-doped carbon) directly carbonized from the pure PIL. Furthermore, its hierarchical porous architectures played an important part in the process of CO 2 capture, which was described briefly as follows: the synergistic effect of mesopores and micropores could accelerate the CO 2 molecules’ transportation and storage. Meanwhile, the appropriate microporous size distribution of NDPC-1-800 was conducive to enhancing CO 2 /N 2 selectivity. This study was intended to open up a new pathway for designing N-doped porous carbons combining both PILs and the multifunctional Fe-based template potassium ferricyanide with wonderful gas adsorption and separation performance.

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Section: Results and Discussionmentioning

confidence: 70%

Constructing Hierarchically Porous N-Doped Carbons Derived from Poly(ionic liquids) with the Multifunctional Fe-Based Template for CO₂ Adsorption

et al. 2021

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“…The G, D1, D3, and D4 Raman bands of the carbon replicas before and after heat-treatment were fitted in the ranges specified by Coccato et al (2015) and Zhang et al (2015c). D5-band positioned between 1,599 and 1,635 cm −1 was not fitted because of its virtual indistinguishability with G-band.…”

Section: Resultsmentioning

confidence: 99%

“…Before the heat treatment of the inverse carbon replica, a hierarchical carbonaceous material with micro-, meso-, and macroporosity was created, as proved by the N 2 sorption results depicted in Figure 4. Such a material with high surface area and high nitrogen content could find application in CO 2 capture (D'Alessandro et al, 2010; Zhang et al, 2015c).…”

Section: Discussionmentioning

confidence: 99%

Nano-casted N-Doped Carbon Created From a Task-Specific Protic Salt and Controlled Porous Glass

et al. 2019

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3-dimensionally interconnected macroporous carbons are versatile materials that can be used in catalysis, electrochemical devices, and separation technology. Herein, the synthesis of a nitrogen doped carbonaceous material with a well-defined nanoarchitecture via nano-casting is demonstrated. A novel carbon source, a task-specific protic salt, has been proposed to create nitrogen doped carbon by direct carbonization within the pores of controlled macroporous glass. After the removal of macroporous glass from the composite using an aqueous sodium hydroxide solution and upon further heat treatment, an oxidation resistant doped carbon with high nitrogen content (6 mass %) is obtained. The materials formed during the different stages of the nano-casting process exhibit interesting properties such as hierarchical porosity, very high nitrogen content (15 mass %), and increased oxidational stability. A combination of different properties to create tailor-made materials for different applications using this technique is possible.

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“…166,167 Resulting from a detailed investigation of the relationship between the precursor structures and the resulting carbon materials, 167 it has become possible to prepare N-doped carbons with controllable N content, 168 and high surface areas with controllable pore structures with or without the use of hard templates. 171 The resulting N-doped carbons exhibit very interesting properties, such as high O 2 reduction activity, 170,172 high CO 2 adsorption capability, 171,173 and high electric double layer capacitance. 170 These low-cost and versatile precursors are promising building blocks for new carbon materials.…”

Section: Il and Nanocarbon Materialsmentioning

confidence: 99%

“…[166][167][168][169][170][171][172][173] Instead of using traditional polymer precursors and complex procedures to prepare N-doped carbons, easily prepared and widely obtainable nitrogencontaining protic ILs/protic salts are used as novel small molecule precursors for the preparation of carbon materials via direct carbonization, without any other treatment (Fig. 14).…”

Section: Il and Nanocarbon Materialsmentioning

confidence: 99%

Design and Materialization of Ionic Liquids Based on an Understanding of Their Fundamental Properties

Watanabe

2016

Electrochemistry

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Ionic liquids (ILs) are defined as salts that have melting points lower than 100°C. Most are organic salts, and these may be designed and tailored to have suitable properties. ILs are recognized as a third group of solvents (and electrolytes), after water and organic solvents. They are characterized by their unique properties such as nonvolatilities, high thermal stabilities, and high ionic conductivities. In this article, our work on the design and preparation of ILs is briefly reviewed. The concept of ionicity is proposed as a metric to characterize the basic nature (dissociativity) of ILs, which is affected by the Lewis acidity/basicity of cations/anions (i.e., coulombic interactions), the directionality of interactions between cations and anions, and van der Waals interactions between ions. The ionicity of ILs is dominated by a subtle balance between coulombic and van der Waals interactions, which clearly discriminates ILs from conventional high-temperature inorganic molten salts. Here, the design of protic ILs for fuel cell electrolytes, electron-transporting ILs for dye-sensitized solar cell electrolytes, and Li + -conducting solvate ILs for lithium battery electrolytes are discussed based on an understanding of the fundamental properties of ILs. Furthermore, the combination of ILs with polymers and colloidal particles affords intriguing quasi-solid materials (ion gels), and the ion transport in these gels is decoupled from the mechanical relaxation time of these materials, yielding new solid electrolytes. The possibility of temperature and photo-sensitive solubility dependence of polymers in ILs allows the creation of stimuli-responsive materials. Finally, protic ILs/protic salts are demonstrated to be good precursors for N-doped carbon materials.

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One-step, template-free synthesis of highly porous nitrogen/sulfur-codoped carbons from a single protic salt and their application to CO₂ capture

Cited by 34 publications

References 84 publications

Constructing Hierarchically Porous N-Doped Carbons Derived from Poly(ionic liquids) with the Multifunctional Fe-Based Template for CO₂ Adsorption

Constructing Hierarchically Porous N-Doped Carbons Derived from Poly(ionic liquids) with the Multifunctional Fe-Based Template for CO₂ Adsorption

Nano-casted N-Doped Carbon Created From a Task-Specific Protic Salt and Controlled Porous Glass

Design and Materialization of Ionic Liquids Based on an Understanding of Their Fundamental Properties

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One-step, template-free synthesis of highly porous nitrogen/sulfur-codoped carbons from a single protic salt and their application to CO2 capture

Cited by 34 publications

References 84 publications

Constructing Hierarchically Porous N-Doped Carbons Derived from Poly(ionic liquids) with the Multifunctional Fe-Based Template for CO2 Adsorption

Constructing Hierarchically Porous N-Doped Carbons Derived from Poly(ionic liquids) with the Multifunctional Fe-Based Template for CO2 Adsorption

Nano-casted N-Doped Carbon Created From a Task-Specific Protic Salt and Controlled Porous Glass

Design and Materialization of Ionic Liquids Based on an Understanding of Their Fundamental Properties

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One-step, template-free synthesis of highly porous nitrogen/sulfur-codoped carbons from a single protic salt and their application to CO₂ capture

Constructing Hierarchically Porous N-Doped Carbons Derived from Poly(ionic liquids) with the Multifunctional Fe-Based Template for CO₂ Adsorption

Constructing Hierarchically Porous N-Doped Carbons Derived from Poly(ionic liquids) with the Multifunctional Fe-Based Template for CO₂ Adsorption