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Metallurgical pyrolysis toward Co@Nitrogen-doped carbon composite for lithium storage

Yanyan Liu, Kang Sun, Jianchun Jiang, Wenshu Zhou, Yuan Shang, Chenxia Du, Baojun Li

2020Green Energy & Environment21 citationsDOIOpen Access PDF

Abstract

Elemental state matter-heteroatom-doped carbon composites are of great importance for the development of anode in lithium ion batteries (LIBs). In this article, metal–organic frameworks (MOFs) are adopted as precursor to prepare Co composites via metallurgical pyrolysis under controllable conditions. The obtained nitrogen-doped porous carbon-Co nanocomposite possesses core–shell structure (Co@C–N). Co@C–N exhibits the best Li storage performances as anode active matter. After the 200th cycles at current density of 0.2 A g −1 , a reversible capacity of 870 mAh g −1 is retained. A reversible capacity of 275 mAh g −1 still maintains with 5 A g −1 . Co@C–N presents a high reversible capacity with excellent cycle stability. Considering the corresponding experimental and theoretical results, the Co 0 -based N-doped porous carbon composite is proposed to work as LIBs anode matter. These results provide a new design idea for electrode matters of metallic ion battery, and demonstrate that MOFs pyrolysis is an effective method for the construction of elemental state anode materials. Co based metal–organic frameworks are used as pyrolysis precursor to prepare nitrogen-doped carbon-Co composites possessing core–shell@sheet structure. The experimental results, combining with the theoretical calculation, demonstrate an effective metallurgical method for the construction of elemental state Li storage materials.

Topics & Concepts

AnodePyrolysisMaterials scienceCarbon fibersComposite numberLithium (medication)NanocompositeHeteroatomChemical engineeringMetal-organic frameworkBattery (electricity)NitrogenLithium-ion batteryElectrodeNanotechnologyComposite materialChemistryAdsorptionOrganic chemistryMedicineQuantum mechanicsPower (physics)EngineeringEndocrinologyPhysicsPhysical chemistryRing (chemistry)Advancements in Battery MaterialsSupercapacitor Materials and FabricationMXene and MAX Phase Materials
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