Perspectives on<scp>Li‐ion</scp>battery categories for electric vehicle applications: A review of state of the art

Camargos, Pedro H.; Santos, Pedro Henrique Jacinto Dos; Santos, Igor R.; Ribeiro, Gabriel S.; Caetano, Ricardo Elias

doi:10.1002/er.7993

Cited by 69 publications

(37 citation statements)

References 141 publications

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“…The Raman spectra of CMK-5, Mn 3 O 4 (x)@CMK-5, and Ni(y)-Mn 3 O 4 (1) @CMK-5 are shown in Figure S6 (SI). The characteristic carbon peaks due to stretching vibration of sp 2hybridized disordered carbon (D band) and E 2g mode of vibration of in-plane sp 2 -hybridized graphitic carbon (G band) were observed at 1337 and 1583 cm À1 , respectively. 21,52 The degree of graphitization of carbon materials can be assessed from the peak intensity ratio of D and G bands (ie, I D /I G ).…”

Section: X-ray Photoelectron and Raman Spectroscopic Analysismentioning

confidence: 99%

“…Currently, lithium-ion batteries (LIBs) are progressively employed in electric vehicles (EVs) and other electronic gadgets owing to their superior energy and power efficiency than other metal-ion batteries. 1,2 However, there is an urgent need to produce high energy and power density LIBs, for example, to increase the range and speed of EVs and other such high-end applications, to cope with the demand. Therefore, novel electrode systems involving the use of multifunctional materials are utmost important to enhance the electrochemical performance, better safety, lower cost, and longer cycle life of LIBs.…”

Section: Introductionmentioning

confidence: 99%

“…Rechargeable batteries become increasingly important as the demand for clean energy has remarkably increased in the last couple of years to sidestep fossil fuel. Currently, lithium‐ion batteries (LIBs) are progressively employed in electric vehicles (EVs) and other electronic gadgets owing to their superior energy and power efficiency than other metal‐ion batteries 1,2 . However, there is an urgent need to produce high energy and power density LIBs, for example, to increase the range and speed of EVs and other such high‐end applications, to cope with the demand.…”

Section: Introductionmentioning

confidence: 99%

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New insights into the outstanding performances of nickel‐doped manganese oxide nanoparticles embedded in a 3D carbon nanopipes framework as anode for lithium and sodium‐ion batteries

Saikia

Deka

Zeng

et al. 2022

Intl J of Energy Research

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A new nanocomposite system based on Ni-doped Mn 3 O 4 nanoparticles embedded in three-dimensional porous carbon nanopipes framework CMK-5 is developed by combination of repeat templating and wet-impregnation techniques to evaluate its performances as anode for rechargeable batteries. The nanocomposite materials are synthesized by varying the Mn 3 O 4 and nickel amounts. Among the nanocomposites, the Ni(5)-Mn 3 O 4 (1)@CMK-5 anode exhibits outstanding discharge capacity of 1269 mA h g À1 after 200 cycles and 832 mA h g À1 beyond 500 cycles at 100 and 1000 mA g À1 , respectively, for lithium-ion batteries (LIBs). Even at high current of 2000 mA g À1 , the electrode possesses the capacity of 669 mA h g À1 . When the Ni(5)-Mn 3 O 4 (1) @CMK-5 anode is used in sodium-ion batteries (SIBs), it provides remarkable discharge capacities of 490 and 334 mA h g À1 after 500 cycles at 50 and 100 mA g À1 , respectively. The excellent electrochemical performances of the Ni(5)-Mn 3 O 4 (1)@CMK-5 nanocomposite reveal its promising potentials as anode for LIBs and SIBs.

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Section: X-ray Photoelectron and Raman Spectroscopic Analysismentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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New insights into the outstanding performances of nickel‐doped manganese oxide nanoparticles embedded in a 3D carbon nanopipes framework as anode for lithium and sodium‐ion batteries

Saikia

Deka

Zeng

et al. 2022

Intl J of Energy Research

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“…Li-ion batteries (LIBs) are the most remarkable success case in the energy storage technology landscape in the last fifty years: [3] their unique configuration allow a fine tuning of performance and properties to meet diversified application needs thanks to the flexible combination of positive electrodes/electrolyte/negative electrodes components. [4,5] Since their market presentation in the early 90s, the most limiting performance factors of LIBs deal with costs and the gravimetric specific capacity limits.…”

Section: Introductionmentioning

confidence: 99%

“…drawbacks, the international R&D community has been working hard in the last thirty years to shift from LiCoO2 to high-capacity positive electrode materials, from carbonatebased liquid electrolytes to solid state ones, and from graphite to high-capacity negative electrode materials. [3,6] Recently the European Union categorized various battery chemistries in "generations" starting from the (+)LiCoO2/EC:DMC LiPF6/graphite(-) Generation 1 (i.e. EC=ethylene carbonate, DMC=dimethyl carbonate) to the innovative Generation 3a and 3b (high capacity lithium-ion batteries), Generation 4a (solid state lithium metal batteries), Generation 4b (lithium-sulphur batteries) and Generation 5 (lithium-oxygen and beyond-lithium batteries).…”

Section: Introductionmentioning

confidence: 99%

Li-Rich Layered Oxides: Structure and Doping Strategies to Enable Co-poor/Co-free Cathodes for Li-Ion Batteries

Silvestri¹,

Tuccillo²,

Celeste³

et al. 2022

Preprint

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Lithium rich layered oxides (LRLO) are a wide class of innovative active materials for positive electrodes in lithium-ion (LIB) and lithium-metal secondary batteries (LMB). LRLOs are over-stoichiometric layered oxides rich in lithium and manganese, with general formula Li1+xTM1-xO2, where TM is a blend of transition metals comprising Mn (main constituent), Ni, Co, Fe and others. Due to the very variable composition and the extended defectivity their structural identity is still debated among researchers being likely an unresolved hybrid between a monoclinic (mC24) and a hexagonal lattice (hR12). Once casted in composite positive electrode films and assembled in LIBs or LMBs, LRLOs can delivery reversible specific capacities above 220-240 mAhg-1, thus beyond any other available intercalation cathode material for LIBs, with mean working potential above 3.3-3.4 V vs Li for hundreds of cycles in liquid aprotic commercial electrodes. In this review we critically outline the recent advancements in the fundamental understanding of the physico-chemical properties of LRLO as well as the most exciting innovations in their battery performance. We focus in particular on the elusive structural identity of these phases, on the complexity of the reaction mechanism in batteries as well as on practical strategies to minimize or remove cobalt from the lattice while preserving the outstanding performance upon cycling.

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Understanding the chemistry of graphene oxide on redox flow lithium‐ion batteries with a view to enhancing the battery's high‐density storage

Onoh,

Nwanya,

Shinde

et al. 2023

Asia-Pacific J Chem Eng

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The use of graphene oxide (GO) has shown potential in improving the performance of redox flow lithium‐ion batteries (RFLIBs). These types of batteries use a liquid electrolyte containing redox‐active species to store and release energy. Despite being scalable, RFLIBs face limitations, namely, low energy density of the electrolyte and reduced cycling stability of the electrodes. However, GO's unique properties, such as its high conductivity as well as large surface area, create an attractive option for enhancing the electrochemical properties of both the electrolyte and electrodes in RFLIBs. When used as an electrode, GO improves the kinetic reversibility reactions, leading to increased electrochemical activity towards redox couples. Charge transfer resistances of positive and negative reactions are reduced, leading to increased voltage energy and efficiency of lithium batteries in terms of energy usage. As redox flow batteries made of lithium ions are an established subsystem and a growing research and development field, there is potential to enhance their performance and reduce costs through the use of GO. The objective of this review is to provide an overview of the chemistry of GO as it pertains to RFLIBs use, covering topics such as its surface chemistry, functionalization, and interactions with redox‐active species, as well as its potential for enhancing high‐density storage of electricity in batteries. Specifically, it will discuss the impact of GO on redox reactions in the electrolyte, including its ability to raise the redox‐active species concentration as well as enhance their stability. The review will also examine how GO impacts the electrodes, including its potential to increase their surface area and conductivity and promote cycling stability. Additionally, the review will address the importance of optimizing the quantity and distribution of GO in both the electrolyte and electrodes of RFLIBs.

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Perspectives onLi‐ionbattery categories for electric vehicle applications: A review of state of the art

Cited by 69 publications

References 141 publications

New insights into the outstanding performances of nickel‐doped manganese oxide nanoparticles embedded in a 3D carbon nanopipes framework as anode for lithium and sodium‐ion batteries

New insights into the outstanding performances of nickel‐doped manganese oxide nanoparticles embedded in a 3D carbon nanopipes framework as anode for lithium and sodium‐ion batteries

Li-Rich Layered Oxides: Structure and Doping Strategies to Enable Co-poor/Co-free Cathodes for Li-Ion Batteries

Understanding the chemistry of graphene oxide on redox flow lithium‐ion batteries with a view to enhancing the battery's high‐density storage

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