Emergence of Novel 2D Materials for High-Performance Supercapacitor Electrode Applications: A Brief Review

Tomy, Merin; Rajappan, Athira Ambika; Vm, Vimuna; Xavier, T.S.

doi:10.1021/acs.energyfuels.1c02743

Cited by 100 publications

(69 citation statements)

References 177 publications

(424 reference statements)

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“…The performance of 2D materials is hindered by atmospheric factors like humidity, electrolyte evaporation due to high temperature, and undesirable chemical reactions. The nanocomposites of 2D layered materials with other conducting materials may solve many of these issues with the cost of some drop in performance but are applicable for practical applications in electrocatalysis [ 255 ]. In nanofluidics, 2D materials often undergo reduction or cross-linkage instead of forming a desirable laminar structure.…”

Section: Primary Challengesmentioning

confidence: 99%

2D materials: increscent quantum flatland with immense potential for applications

et al. 2022

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Quantum flatland i.e., the family of two dimensional (2D) quantum materials has become increscent and has already encompassed elemental atomic sheets (Xenes), 2D transition metal dichalcogenides (TMDCs), 2D metal nitrides/carbides/carbonitrides (MXenes), 2D metal oxides, 2D metal phosphides, 2D metal halides, 2D mixed oxides, etc. and still new members are being explored. Owing to the occurrence of various structural phases of each 2D material and each exhibiting a unique electronic structure; bestows distinct physical and chemical properties. In the early years, world record electronic mobility and fractional quantum Hall effect of graphene attracted attention. Thanks to excellent electronic mobility, and extreme sensitivity of their electronic structures towards the adjacent environment, 2D materials have been employed as various ultrafast precision sensors such as gas/fire/light/strain sensors and in trace-level molecular detectors and disease diagnosis. 2D materials, their doped versions, and their hetero layers and hybrids have been successfully employed in electronic/photonic/optoelectronic/spintronic and straintronic chips. In recent times, quantum behavior such as the existence of a superconducting phase in moiré hetero layers, the feasibility of hyperbolic photonic metamaterials, mechanical metamaterials with negative Poisson ratio, and potential usage in second/third harmonic generation and electromagnetic shields, etc. have raised the expectations further. High surface area, excellent young’s moduli, and anchoring/coupling capability bolster hopes for their usage as nanofillers in polymers, glass, and soft metals. Even though lab-scale demonstrations have been showcased, large-scale applications such as solar cells, LEDs, flat panel displays, hybrid energy storage, catalysis (including water splitting and CO2 reduction), etc. will catch up. While new members of the flatland family will be invented, new methods of large-scale synthesis of defect-free crystals will be explored and novel applications will emerge, it is expected. Achieving a high level of in-plane doping in 2D materials without adding defects is a challenge to work on. Development of understanding of inter-layer coupling and its effects on electron injection/excited state electron transfer at the 2D-2D interfaces will lead to future generation heterolayer devices and sensors.

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Section: Primary Challengesmentioning

confidence: 99%

2D materials: increscent quantum flatland with immense potential for applications

et al. 2022

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“…As supercapacitors offer a specific power density, rapid charge and discharge process, and long-term durability, thus they have emerged as a popular system for certain applications in vehicles, cranes, emerging hybrid automobiles, G-series high-speed trains, and so on. , Nevertheless, supercapacitors are mostly made of a carbonaceous matrix and have some fatal drawbacks of delivering low energy density (∼10 Wh kg –1 ) in modern commercial applications due to a low potential window and limited electrochemically active surface functionality. ,, To overcome this issue, since last decade, asymmetric supercapacitors (ASCs) are assembled by different positive and negative electrode materials to successfully modulate the energy density without disturbing their power density. Currently, researchers have focused on transition metal-based compounds as a positive electrode and carbon-based materials as a negative electrode to enhance the voltage window and overall capacitance of supercapacitors. − Out of which, transition metal phosphides (TMPs) can be investigated as one of the best valuable electrode materials in the fields of electrocatalysis, − batteries, − supercapacitors, − and other energy device applications. , It is due to rich valences, weak ionic bond due to a lower electronegativity, and superior electronic conductivity of TMPs that make them environmentally stable, kinetically favorable for faster charge transport, and sustainable under high applied potentials. , Thus, TMPs have emerged as new battery-type electrode materials and gained more attention because they can improve the specific capacity along with the better rate capability of devices as compared to other electroactive materials. − …”

Section: Introductionmentioning

confidence: 99%

Boosting the Supercapacitive Performance via Incorporation of Vanadium in Nickel Phosphide Nanoflakes: A High-Performance Flexible Renewable Energy Storage Device

Afshan¹,

Kumar²,

Aziz³

et al. 2022

Energy Fuels

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Developing an efficient capacitive matrix along with the emergence of battery-type characteristics is the key priority function to attain high-performance asymmetric supercapacitors (ASCs). The rational design of metal-rich transition metal phosphides with a remarkable electrochemical activity and rich valence state possesses an efficient approach to overcome their limitation toward the low-rate capability with poor cycle life against metal deficient counterparts for their practical application. Herein, the metal-rich porous vanadium-doped nickel phosphide (V-Ni12P5) nanoflakes have been synthesized via a one-step solvothermal method. The as-synthesized electrode delivers a high specific capacity of 1455 F g–1 at a current density of 1 A g–1, and the corresponding assembled ASC device delivers a maximum energy density of 38.41 Wh kg–1 at a power density of 626.48 W kg–1 as well as long term cycling stability with 76.3% capacitive retention after 11,000 cycles. The assembled four sets of 1 × 1 cm2 devices in series designed with the help of a flexible carbon cloth matrix can light a red LED for 3 min and can rotate a 3 V home-designed windmill device for 1 min with in situ charging via a 6 V standard silicon solar panel illuminated by 50 W street light for 1 min. The flexible device can retain its invariant capacitive performance under rigorous twisting and bending at variable angles of 0, 90, and 135°. The significant enhancement (∼60%) of electrochemical activity for doped systems is mainly attributed to the generation of partial positive polarity on the metal centers and thereby induces strong adhesion of electrolytes under prolonged operation. Hence, this present work demonstrates the excellent capability of V-Ni12P5 nanoflakes toward the realistic drive of renewable energy conversion, unveiling the booming technology toward reliable high-performance hybrid energy-storage systems.

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“…However, the poor specific energy (carbonaceous material) and insufficient cyclic performance ( pseudocapacitor) of the materials have been resolved through a combined effect in their hybrid form. [14][15][16] Therefore, research on the synthesis of hybrid electrode materials and their improved supercapacitor performances has become of key interest. In particular, different metal sulfides, selenides, and carbonaceous hybrids are famous for the various synthetic routes through which they can be synthesized and their good electrical conductivity, variable oxidation state, narrow bandgap, and high capacitance value.…”

Section: Introductionmentioning

confidence: 99%

“…In particular, different metal sulfides, selenides, and carbonaceous hybrids are famous for the various synthetic routes through which they can be synthesized and their good electrical conductivity, variable oxidation state, narrow bandgap, and high capacitance value. 10,15,17,18 The presence of additional carbonaceous support (such as graphene and carbon nanotubes) acts as a templating agent to avoid particle aggregation and generate a conducting network to further improve conductivity. 12,14,19 Likewise, in the two-dimensional (2D) structures of graphene and other carbonaceous materials, a new kind of 2D material known as transition metal carbidebased MXenes (Ti 3 C 2 ) can be produced by following a selective etching process from the ternary MAX phase (Ti 3 AlC 2 ) with a common formula of M n+1 AX n (where M represents transition metals, A is for metals like Al and X n is for the number of carbon or nitrogen elements).…”

Section: Introductionmentioning

confidence: 99%

Tetra germanium nonaselenide enwrapped with reduced graphene oxide and functionalized carbon nanotubes (Ge₄Se₉/RGO/FCNTs) hybrids for improved energy storage performances

et al. 2022

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Emergence of Novel 2D Materials for High-Performance Supercapacitor Electrode Applications: A Brief Review

Cited by 100 publications

References 177 publications

2D materials: increscent quantum flatland with immense potential for applications

2D materials: increscent quantum flatland with immense potential for applications

Boosting the Supercapacitive Performance via Incorporation of Vanadium in Nickel Phosphide Nanoflakes: A High-Performance Flexible Renewable Energy Storage Device

Tetra germanium nonaselenide enwrapped with reduced graphene oxide and functionalized carbon nanotubes (Ge₄Se₉/RGO/FCNTs) hybrids for improved energy storage performances

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Emergence of Novel 2D Materials for High-Performance Supercapacitor Electrode Applications: A Brief Review

Cited by 100 publications

References 177 publications

2D materials: increscent quantum flatland with immense potential for applications

2D materials: increscent quantum flatland with immense potential for applications

Boosting the Supercapacitive Performance via Incorporation of Vanadium in Nickel Phosphide Nanoflakes: A High-Performance Flexible Renewable Energy Storage Device

Tetra germanium nonaselenide enwrapped with reduced graphene oxide and functionalized carbon nanotubes (Ge4Se9/RGO/FCNTs) hybrids for improved energy storage performances

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Tetra germanium nonaselenide enwrapped with reduced graphene oxide and functionalized carbon nanotubes (Ge₄Se₉/RGO/FCNTs) hybrids for improved energy storage performances