Precisely Designed Mesoscopic Titania for High-Volumetric-Density Pseudocapacitance

Lan, Kun; Liu, Lu; Zhang, Junye; Wang, Ruicong; Zu, Lianhai; Lv, Zirui; Wei, Qiulong; Zhao, Dongyuan

doi:10.1021/jacs.1c03433

Cited by 34 publications

(34 citation statements)

References 47 publications

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“…[11][12][13] Besides, for supercapacitor electrodes, the design of more doses of active materials means that there exists plenty of active sites available for reversible redox reactions. [14] As a result, it seems desirable to configure a supercapacitor electrode with a high mass loading (per unit area or volume) of active materials, such as a relatively dense distribution or a large thickness. However, such designs usually tend to cause the sluggish electron/ion diffusion, as well as the insufficient use of active materials, which instead limits the overall performance of supercapacitors.…”

mentioning

confidence: 99%

A Simple Strategy for Constructing Hierarchical Composite Electrodes of PPy‐Posttreated 3D‐Printed Carbon Aerogel with Ultrahigh Areal Capacitance over 8000 mF cm^–2

Yang

Cui

Han

et al. 2021

Adv Materials Technologies

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the specific capacitances of supercapacitor electrodes measured by area or volume are the primary consideration for electrochemical energy storage within miniaturized footprint area. [11][12][13] Besides, for supercapacitor electrodes, the design of more doses of active materials means that there exists plenty of active sites available for reversible redox reactions. [14] As a result, it seems desirable to configure a supercapacitor electrode with a high mass loading (per unit area or volume) of active materials, such as a relatively dense distribution or a large thickness. However, such designs usually tend to cause the sluggish electron/ion diffusion, as well as the insufficient use of active materials, which instead limits the overall performance of supercapacitors. [15,16] Carbon aerogel (CA) is a type of hierarchically porous material ranging from micropores to macropores, which exhibits excellent application prospects in catalysis, adsorption, sensing, water evaporation, bone regeneration, electromagnetic shielding, and energy storage. [17][18][19][20][21][22][23][24] Especially, because of the excellent properties such as abundant porosity, ultrahigh specific surface area, good electrical conductivity, excellent infiltration, and good mass transfer ability, CA is considered as a promising electrode material in supercapacitors. [13,[25][26][27] Over the past few years, many efforts have been focused on modifying the pore size distribution of CA to further improve specific capacitance. The abundant micropores and small mesopores for CA are beneficial to the increase of specific capacitance due to a significant increase in specific surface area and active sites. [28] Interestingly, larger mesopores (20-50 nm) are detrimental to the specific capacitance due to the barrier effect for ion diffusion. [29,30] The precise control of sol-gel process was usually used to avoid these larger mesopores. [31] In addition, macropores, as well as micrometer-level or even sub-millimeter-level channels are also conducive to the improvement of specific capacitance, because of the unimpeded channels for electrolyte entry and replacement. [25,28,[32][33][34][35] However, excessive larger channels are unfavorable for their mechanical properties and loading amount of active materials. [16,23] Therefore, the hierarchical pores ranging from nanometer to sub-millimeter scale other than larger mesopores A well-designed pore structure and optimized interface will improve specific capacitances of carbon-based supercapacitor electrodes significantly. Herein, a simple strategy is used to prepare the hierarchically porous 3D-printed carbon aerogel (CA) electrodes via combining direct ink writing, freezing drying, carbonization, and polypyrrole (PPy) posttreatment. The 3D-printed CA electrodes without PPy present a quasi-proportional increase in areal capacitance as thickness, achieving an extremely high areal capacitance of 6875 mF cm -2 under a thickness of 2.2 mm. Additionally, PPy posttreated 3D-printed CA (PPy@CA) electrode has improve...

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A Simple Strategy for Constructing Hierarchical Composite Electrodes of PPy‐Posttreated 3D‐Printed Carbon Aerogel with Ultrahigh Areal Capacitance over 8000 mF cm^–2

Yang

Cui

Han

et al. 2021

Adv Materials Technologies

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“…[78][79][80] Considerable interest is emerging in creating materials that combine the short charging times and long cycle life of pseudocapacitive nanomaterials with a high tap density for enhanced areal capacity. With this aim, a mesoscopic TiO 2 microsphere anode was designed, in which the cylindrical TiO 2 nanocrystals were radially aligned from the microsphere center and with conductive carbon distributed in the whole mesostructured frameworks [81] (Figure 10a). The ordered arrangement of TiO 2 nanocrystals provides a greatly improved tap density (1.1-1.7 g cm À 3 ), which in turn increases the volume and areal capacities of the electrode.…”

Section: D Mesoscopic Tio 2 For High-volumetric-density Pseudocapacit...mentioning

confidence: 99%

“…g) Separation of the capacitive and diffusion currents in meso-TiO 2 at 1 mV s À 1 . Reproduced from Ref [81]. with permission.…”

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Versatile Synthesis of Mesoporous Crystalline TiO₂ Materials by Monomicelle Assembly

2022

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Mesoscale TiO2 structures have realized many technological applications—ranging from catalysis and biomedicine to energy storage and conversion—because of their large mesoporosities offering desirable accessibility and mass transport. Tailoring mesoporous TiO2 structures with novel mesoscopic and microscopic configurations is envisaged to offer ample opportunities for further applications. In this Review, we explain how to synthesize novel mesoporous TiO2 materials and present recent examples. An emphasis is placed on a “monomicelle assembly” strategy as an emerging and powerful approach to direct the formation of mesostructured TiO2 with precise control over its structural orientations and architectures. Furthermore, typical examples of mesoporous TiO2 for applications in batteries and photocatalysis are highlighted. The Review ends with an outlook towards the synthesis of mesoporous TiO2 with tailored architectures by self‐assembly, which could pave the way for developing advanced energy conversion and storage devices.

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“…[8,9] Materials that have exhibited intercalation pseudocapacitive responses have sufficiently fast solid-state diffusion and an absence of phase transitions upon intercalation. [7][8][9][10][11][12][13][14] The introduction of dopants or other defects have been used to increase the rates of solid-state diffusion with examples for Cu[Fe(CN) 6 ] 0.63 * & 0.37 * 3.4H 2 O, [15] T-Nb 2 O 5 , [16][17][18] MoO 3 , [19] TiO 2 , [20,21] and others. [22,23] Nanoscale materials can also differ from bulk analogs, for example, nanoscale anatase can lithiate as a solid solution whereas larger anatase crystals undergo a phase separation of discrete lithium rich and lithium poor domains.…”

Section: Introductionmentioning

confidence: 99%

“…Intercalation pseudocapacitive responses exhibit surface‐limited kinetics by definition, where the current response is proportional to the voltage sweep rate ( v ) [8,9] . Materials that have exhibited intercalation pseudocapacitive responses have sufficiently fast solid‐state diffusion and an absence of phase transitions upon intercalation [7–14] . The introduction of dopants or other defects have been used to increase the rates of solid‐state diffusion with examples for Cu[Fe(CN) 6 ] 0.63 ⋅□ 0.37 ⋅3.4H 2 O, [15] T‐Nb 2 O 5 , [16–18] MoO 3 , [19] TiO 2 , [20,21] and others [22,23] .…”

Section: Introductionmentioning

confidence: 99%

Faster Intercalation Pseudocapacitance Enabled by Adjustable Amorphous Titania Where Tunable Isomorphic Architectures Reveal Accelerated Lithium Diffusivity

Bergh

Larison

Fornerod

et al. 2022

Batteries & Supercaps

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Intercalation pseudocapacitance is a faradaic electrochemical phenomenon with high power and energy densities, combining the attractive features of capacitors and batteries, respectively. Intercalation pseudocapacitive responses exhibit surface-limited kinetics by definition, without restriction from the collective of diffusion-based processes. The surface-limited threshold (SLT) corresponds to the maximum voltage sweep rate (v SLT ) exhibiting a predominantly surface-limited current response prior to the onset of diffusion-limitations. Prior studies showed increased lithium diffusivity for amorphous titania compared to anatase. Going beyond prior binary comparisons, here a continuum of amorphous titania configurations were prepared using a series of calcination temperatures to tailor both amorphous character and content. The corresponding amorphous-phase v SLT increased monotonically by 317 % with lowered calcination temperatures. Subsequent isomorphic comparisons varying a single transport parameter at a time identified solid-state lithium diffusion as the dominant diffusive constraint. Thus, performance improvements were linked to increasing the lithium diffusivity of the amorphous phase with decreased calcination temperature. This remarkably enabled 95 % capacity retention (483 � 17 C/g) with 30 s of delithiation (120 C equivalent). These results highlight how isomorphic sample series can reveal previously unidentified trends by reducing ambiguity and reiterate the potential of amorphization to realize increased performance in known materials.[a] W. van den Bergh, T.

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Precisely Designed Mesoscopic Titania for High-Volumetric-Density Pseudocapacitance

Cited by 34 publications

References 47 publications

A Simple Strategy for Constructing Hierarchical Composite Electrodes of PPy‐Posttreated 3D‐Printed Carbon Aerogel with Ultrahigh Areal Capacitance over 8000 mF cm^–2

A Simple Strategy for Constructing Hierarchical Composite Electrodes of PPy‐Posttreated 3D‐Printed Carbon Aerogel with Ultrahigh Areal Capacitance over 8000 mF cm^–2

Versatile Synthesis of Mesoporous Crystalline TiO₂ Materials by Monomicelle Assembly

Faster Intercalation Pseudocapacitance Enabled by Adjustable Amorphous Titania Where Tunable Isomorphic Architectures Reveal Accelerated Lithium Diffusivity

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Precisely Designed Mesoscopic Titania for High-Volumetric-Density Pseudocapacitance

Cited by 34 publications

References 47 publications

A Simple Strategy for Constructing Hierarchical Composite Electrodes of PPy‐Posttreated 3D‐Printed Carbon Aerogel with Ultrahigh Areal Capacitance over 8000 mF cm–2

A Simple Strategy for Constructing Hierarchical Composite Electrodes of PPy‐Posttreated 3D‐Printed Carbon Aerogel with Ultrahigh Areal Capacitance over 8000 mF cm–2

Versatile Synthesis of Mesoporous Crystalline TiO2 Materials by Monomicelle Assembly

Faster Intercalation Pseudocapacitance Enabled by Adjustable Amorphous Titania Where Tunable Isomorphic Architectures Reveal Accelerated Lithium Diffusivity

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A Simple Strategy for Constructing Hierarchical Composite Electrodes of PPy‐Posttreated 3D‐Printed Carbon Aerogel with Ultrahigh Areal Capacitance over 8000 mF cm^–2

A Simple Strategy for Constructing Hierarchical Composite Electrodes of PPy‐Posttreated 3D‐Printed Carbon Aerogel with Ultrahigh Areal Capacitance over 8000 mF cm^–2

Versatile Synthesis of Mesoporous Crystalline TiO₂ Materials by Monomicelle Assembly