Green algae and gelatine derived nitrogen rich carbon as an outstanding competitor to Pt loaded carbon catalysts

Ilnicka, Anna; Skorupska, Małgorzata; Tyc, Magdalena; Kowalska, Kinga; Kamedulski, Piotr; Zieliński, Wojciech; Łukaszewicz, Jerzy P.

doi:10.1038/s41598-021-86507-5

Cited by 21 publications

(8 citation statements)

References 39 publications

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“…[194] Furthermore, Ilnicka et al prepared green algae and gelatine-derived nitrogen-rich carbon catalysts as ORR electrocatalysts, showing superior ORR performance in alkaline media compared to commercially available electrocatalysts. [201] While biomass can be easily transformed into novel carbon nanostructures with superior ORR activity, it usually contains little or no nitrogen, requiring thus a second N-source that may result in poor homogeneity of the final materials due to the absence of molecular mixing. [43,87] Meanwhile, fine structural control of carbons produced by this method is difficult to achieve.…”

Section: Biomass Conversionmentioning

confidence: 99%

Nitrogen‐Rich Carbonaceous Materials for Advanced Oxygen Electrocatalysis: Synthesis, Characterization, and Activity of Nitrogen Sites

Meng

Morales

et al. 2022

Adv Funct Materials

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Nitrogen‐doped carbons are among the fastest‐growing class of materials used for oxygen electrocatalysis, namely, the oxygen reduction reaction (ORR) and oxygen evolution reaction (OER), thanks to their low cost, environmental friendliness, excellent electrical conductivity, and scalable synthesis. The perspective of replacing precious metal‐based electrocatalysts with nitrogen‐doped carbon is highly desirable for reducing costs in energy conversion and storage systems. In this review, the role of nitrogen and N‐induced structural defects on the enhanced performance of N‐doped carbon electrocatalysts toward the OER and the ORR as well as their applications for energy conversion and storage technologies is summarized. The synthesis of N‐doped carbon electrocatalysts and the characterization of their nitrogen functional groups and active sites for the conversion of oxygen are also reviewed. The electrocatalytic performance of the main types of N‐doped carbon materials for OER/ORR electrocatalysis are then discussed. Finally, major challenges and future opportunities of N‐doped carbons as advanced oxygen electrocatalysts are highlighted.

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Section: Biomass Conversionmentioning

confidence: 99%

Nitrogen‐Rich Carbonaceous Materials for Advanced Oxygen Electrocatalysis: Synthesis, Characterization, and Activity of Nitrogen Sites

Meng

Morales

et al. 2022

Adv Funct Materials

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“…To expose more active sites, obtaining a high specific surface area, improving the catalyst structure, loading active particles on carbon-based substrates, or introducing functional groups are effective strategies. For example, the as-prepared, metal-free mesoporous carbons possessed a high density of N-containing active sites and a high specific surface area (Ilnicka et al, 2021). Zan et al (2021) prepared an ultrathin carbon nanosheet with a thickness of 1-2 nm, which can incredibly increase the specific surface area and obtain a larger current density.…”

Section: Oxygen Reduction Reactionmentioning

confidence: 99%

“…Feng et al (2018) synthesized catalysts that have more than twice the current density of Pt/C electrodes at the same catalyst loading due to the super absorption properties of graphene layers and oxygen bubbles stabilizing ability of dendritic interstices. The porous structure provides similar properties, with strong interaction with O 2 bubbles (Lu et al, 2016;Ilnicka et al, 2021). In the porous nanosheet catalyst synthesized by 17.4% of the macropores were for substance transport, and 82.6% of the mesopores were for the diffusion of reactants and products.…”

Section: Oxygen Reduction Reactionmentioning

confidence: 99%

Nanostructured carbon electrocatalysts for clean energy conversion and storage: A mini review on the structural impact

et al. 2022

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Electrochemical conversions of carbon dioxide, water, oxygen, and nitrogen have offered effective ways to relieve the problems of carbon dioxide over-emission and fluctuated energy (such as solar, wind, tide, etc.) storage. The key factor that impacts the electrochemical system’s performance is the catalysts employed. Among all the materials, carbon nanomaterials generally exhibit high catalytic activity which is attributed to the high conductivity, large specific surface area, and exposed active sites. Recently, more and more researchers set their sights on applying the carbon nanomaterials in large-scale projects. Herein, it is of great importance to review the most recent studies on carbon nanomaterials in electrochemical applications. This paper summarizes the applications of carbon nanomaterials in electrochemical processes, and the structure impact on the performance. Further, challenges in this field are discussed, which can guide the innovative synthesis of efficient nanostructured carbon electrocatalysts for practical, large-scale energy conversion applications.

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“…At the same time, very high concentrations of heteroatoms and a large amount of defects in the structure can contribute to a decrease in electronic conductivity and disadvantage the oxygen reduction reaction 22 . There are many nitrogen precursors that may be useful for synthesising N-doped carbon catalysts of high activity towards ORR, e.g., melamine 23 , 24 , urea 23 , 25 , adenine 23 , 26 , arginine 23 , 27 , or natural materials, such as green algae or gelatine 28 , 29 . We have demonstrated in our previous studies that such N-doped materials can be derived from amino acids 30 , chitin, and chitosan 31 , 32 , and provide high activity towards ORR.…”

Section: Introductionmentioning

confidence: 99%

The effect of nitrogen species on the catalytic properties of N-doped graphene

Skorupska

Ilnicka

Łukaszewicz

2021

Sci Rep

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The production of effective catalysts in the oxygen reduction reaction (ORR) continues to be a great challenge for scientists. A constant increase in demand for energy storage materials is followed by a proportionate increase in the number of reports on electrocatalyst synthesis. The scientific world focuses on environmentally friendly materials synthesized in accordance with the safest possible. In this work, we developed a facile method of obtaining heavy-metal-free electrode materials that are effective in ORR. Graphene-based catalysts were doped using azodicarbonamide (ADC) as the source of nitrogen, then carbonized at high temperatures in the range of 700–900 °C under inert gas flow. The produced materials were tested as catalysts for ORR, which is the most important reaction for Zn–air batteries and fuel cells. All obtained nitrogen-doped graphene foams showed increased catalytic activity in ORR owing to active sites created by nitrogen functional groups on the graphene surface. This paper shows that carbonization temperature has a significant impact on nitrogen content and that a small percentage of nitrogen may have a positive effect on the catalytic activity of the obtained materials. The number of transferred electrons in ORR was found to range from three to the maximal theoretical value, i.e., four.

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Green algae and gelatine derived nitrogen rich carbon as an outstanding competitor to Pt loaded carbon catalysts

Cited by 21 publications

References 39 publications

Nitrogen‐Rich Carbonaceous Materials for Advanced Oxygen Electrocatalysis: Synthesis, Characterization, and Activity of Nitrogen Sites

Nitrogen‐Rich Carbonaceous Materials for Advanced Oxygen Electrocatalysis: Synthesis, Characterization, and Activity of Nitrogen Sites

Nanostructured carbon electrocatalysts for clean energy conversion and storage: A mini review on the structural impact

The effect of nitrogen species on the catalytic properties of N-doped graphene

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