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603 results on '"Li, Yat"'

1. Interpenetrated Structures for Enhancing Ion Diffusion Kinetics in Electrochemical Energy Storage Devices.

Author

Xue, Xinzhe, Feng, Longsheng, Ren, Qiu, Tran, Cassidy, Eisenberg, Samuel, Pinongcos, Anica, Valdovinos, Logan, Hsieh, Cathleen, Heo, Tae, Worsley, Marcus, Zhu, Cheng, and Li, Yat

Subjects
3D printing, Electrochemical energy storage, Inter-electrode distance, Interpenetrated structure, Ion diffusion length
Abstract

The architectural design of electrodes offers new opportunities for next-generation electrochemical energy storage devices (EESDs) by increasing surface area, thickness, and active materials mass loading while maintaining good ion diffusion through optimized electrode tortuosity. However, conventional thick electrodes increase ion diffusion length and cause larger ion concentration gradients, limiting reaction kinetics. We demonstrate a strategy for building interpenetrated structures that shortens ion diffusion length and reduces ion concentration inhomogeneity. This free-standing device structure also avoids short-circuiting without needing a separator. The feature size and number of interpenetrated units can be adjusted during printing to balance surface area and ion diffusion. Starting with a 3D-printed interpenetrated polymer substrate, we metallize it to make it conductive. This substrate has two individually addressable electrodes, allowing selective electrodeposition of energy storage materials. Using a Zn//MnO2 battery as a model system, the interpenetrated device outperforms conventional separate electrode configurations, improving volumetric energy density by 221% and exhibiting a higher capacity retention rate of 49% compared to 35% at temperatures from 20 to 0 °C. Our study introduces a new EESD architecture applicable to Li-ion, Na-ion batteries, supercapacitors, etc.

Published
2024

3. Regulated Interfacial Proton and Water Activity Enhances Mn2+/MnO2 Platform Voltage and Energy Efficiency

Author

Xue, Xinzhe, Liu, Zhen, Eisenberg, Samuel, Ren, Qiu, Lin, Dun, Coester, Emma, Zhang, Heng, Zhang, Jin Zhong, Wang, Xiao, and Li, Yat

Subjects
Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Chemical sciences
Abstract

Electrolytic MnO2 batteries store charges via the Mn2+/MnO2 two-electron transfer process with higher capacity and voltage than conventional one-electron (Zn2+ or H+) intercalation reactions. Yet, the opposite effect of interfacial H+ on the dissolution/deposition processes and the role of interfacial H2O are rarely discussed. Here we introduce tetrafluoroborate (BF4-) into the sulfate-based electrolyte to regulate interfacial H+ and H2O activity. First, BF4- hydrolysis increases the electrolyte’s acidity, promoting MnO2 dissolution. Second, BF4- forms H-bond networks with interfacial H2O that assist H+ diffusion while retaining a sufficient H2O supply to facilitate MnO2 deposition. As a result, the cathode-free Zn//MnO2 electrolytic cell achieves a high platform of ∼1.92 V and energy efficiency of ∼84.23%. Significantly, the cell delivers 1000 cycles at 1 C with ∼100% Coulombic efficiency and a high energy efficiency retention of 93.65%. Our findings disclose a new strategy to promote Mn2+/MnO2 platform voltage and energy efficiency.

Published
2023

4. Nanocone‐Modified Surface Facilitates Gas Bubble Detachment for High‐Rate Alkaline Water Splitting

Author

Ren, Qiu, Feng, Longsheng, Ye, Congwang, Xue, Xinzhe, Lin, Dun, Eisenberg, Samuel, Kou, Tianyi, Duoss, Eric B, Zhu, Cheng, and Li, Yat

Subjects
Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, alkaline water splitting, bubble detachment, nanocones, Ni catalysts, superaerophobicity, Macromolecular and Materials Chemistry, Interdisciplinary Engineering, Macromolecular and materials chemistry, Materials engineering
Abstract

Abstract: The significant amount of gas bubbles generated during high‐rate alkaline water splitting (AWS) can be detrimental to the process. The accumulation of bubbles will block the active catalytic sites and hinder the ion and electrolyte diffusion, limiting the maximum current density. Furthermore, the detachment of large bubbles can also damage the electrode's surface layer. Here, a general strategy for facilitating bubble detachment is demonstrated by modifying the nickel electrode surface with nickel nanocone nanostructures, which turns the surface into underwater superaerophobic. Simulation and experimental data show that bubbles take a considerably shorter time to detach from the nanocone‐modified nickel foil than the unmodified foil. As a result, these bubbles also have a smaller detachment size and less chance for bubble coalescence. The nanocone‐modified electrodes, including nickel foil, nickel foam, and 3D‐printed nickel lattice, all show substantially reduced overpotentials at 1000 mA cm−2 compared to their pristine counterpart. The electrolyzer assembled with two nanocone‐modified nickel lattice electrodes retains >95% of the performance after testing at ≈900 mA cm−2 for 100 h. The surface NC structure is also well preserved. The findings offer an exciting and simple strategy for enhancing the bubble detachment and, thus, the electrode activity for high‐rate AWS.

Published
2023

5. 3D‐Printed Graded Electrode with Ultrahigh MnO2 Loading for Non‐Aqueous Electrochemical Energy Storage

Author

Lin, Dun, Chandrasekaran, Swetha, Forien, Jean‐Baptiste, Xue, Xinzhe, Pinongcos, Anica, Coester, Emma, Worsley, Marcus A, and Li, Yat

Subjects
Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, additive manufacturing, electrochemical energy storage, graded lattice structure, manganese dioxide, non-aqueous electrolytes, Macromolecular and Materials Chemistry, Interdisciplinary Engineering, Macromolecular and materials chemistry, Materials engineering
Abstract

Abstract: Electrolytic manganese dioxide is one of the promising cathode candidates for electrochemical energy storage devices due to its high redox capacity and ease of synthesis. Yet, high‐loading MnO2 often suffers from sluggish reaction kinetics, especially in non‐aqueous electrolytes. The non‐uniform deposition of MnO2 on a porous current collectors also makes it difficult to fully utilize the active materials at high mass loading. Here, a 3D printed graded graphene aerogel (3D GA) that contains sparsely separated exterior ligaments is developed to create large open channels for mass transport as well as densely arranged interior ligaments providing large ion‐accessible active surface. The unique structural design homogenizes the thickness of electro deposited MnO2 even at an ultrahigh mass loading of ≈70 mg cm−2. The electrode achieves a remarkable volumetric capacity of 29.1 mA h cm−3 in the non‐aqueous electrolyte. A Li‐ion hybrid capacitor device assembled with a graded 3D GA/MnO2 cathode and graded 3D GA/VOx anode exhibits a wide voltage window of 0–4 V and a superior volumetric energy density of 20.2 W h L−1. The findings offer guidance on 3D printed electrode design for supporting ultrahigh loading of active materials and developments of high energy density energy storage devices.

Published
2023

6. Electronic surface reconstruction of TiO2 nanocrystals revealed by resonant inelastic x-ray scattering

Author

Chuang, Cheng-Hao, Chen, Chieh-Ming, Shao, Yu-Cheng, Yeh, Ping-Hung, Chang, Chih-Ming, Pong, Way-Faung, Kapilashrami, Mukes, Glans, Per-Anders, Gul, Sheraz, Wang, Gongming, Li, Yat, Zhang, Jin, Miyawaki, Jun, Niwa, Hideharu, Harada, Yoshihisa, Chen, Jin-Ming, and Guo, Jinghua

Subjects
Physical Sciences, Engineering, Applied Physics
Abstract

The identification of lattice multiphases in TiO2 nanocrystals is studied by high resolution transmission electron microscope and electron diffraction patterns. Based on the spectroscopic analysis using soft x-ray absorption and resonant inelastic soft x-ray scattering, it is believed that the oxygen vacancies at the interface exhibit structural distortion of the TiO68−cluster around the defect site as for the multiphase lattice. We elucidate that the extra 3d electrons nearby induce the inelastic scattering features with the excitation energy dependence owing to different energy relaxation processes, a characteristic of the electron-phonon coupling or the nature of the electron-hole pair at the intermediate state. The manifold dd excitations driven by the strong interaction between Ti-3d and O-2p electrons are noticeably rich, coexisting on both Ti and O sites. This sophisticated experiment can advance the perspective of nanocomposite TiO2 for various interactions of surface Ti3+ in applications of future devices.

Published
2021

8. Carbon doping switching on the hydrogen adsorption activity of NiO for hydrogen evolution reaction.

Author

Kou, Tianyi, Chen, Mingpeng, Wu, Feng, Smart, Tyler J, Wang, Shanwen, Wu, Yishang, Zhang, Ying, Li, Shengtong, Lall, Supriya, Zhang, Zhonghua, Liu, Yi-Sheng, Guo, Jinghua, Wang, Gongming, Ping, Yuan, and Li, Yat

Abstract

Hydrogen evolution reaction (HER) is more sluggish in alkaline than in acidic media because of the additional energy required for water dissociation. Numerous catalysts, including NiO, that offer active sites for water dissociation have been extensively investigated. Yet, the overall HER performance of NiO is still limited by lacking favorable H adsorption sites. Here we show a strategy to activate NiO through carbon doping, which creates under-coordinated Ni sites favorable for H adsorption. DFT calculations reveal that carbon dopant decreases the energy barrier of Heyrovsky step from 1.17 eV to 0.81 eV, suggesting the carbon also serves as a hot-spot for the dissociation of water molecules in water-alkali HER. As a result, the carbon doped NiO catalyst achieves an ultralow overpotential of 27 mV at 10 mA cm-2, and a low Tafel slope of 36 mV dec-1, representing the best performance among the state-of-the-art NiO catalysts.

Published
2020

9. TiN Paper for Ultrafast-Charging Supercapacitors.

Author

Yao, Bin, Li, Mingyang, Zhang, Jing, Zhang, Lei, Song, Yu, Xiao, Wang, Cruz, Andrea, Tong, Yexiang, and Li, Yat

Subjects
Paper-like electrode, Supercapacitors, TiN, Ultrafast charging, Wide voltage window
Abstract

Ultrafast-charging energy storage devices are attractive for powering personal electronics and electric vehicles. Most ultrafast-charging devices are made of carbonaceous materials such as chemically converted graphene and carbon nanotubes. Yet, their relatively low electrical conductivity may restrict their performance at ultrahigh charging rate. Here, we report the fabrication of a porous titanium nitride (TiN) paper as an alternative electrode material for ultrafast-charging devices. The TiN paper shows an excellent conductivity of 3.67 × 104 S m-1, which is considerably higher than most carbon-based electrodes. The paper-like structure also contains a combination of large pores between interconnected nanobelts and mesopores within the nanobelts. This unique electrode enables fast charging by simultaneously providing efficient ion diffusion and electron transport. The supercapacitors (SCs) made of TiN paper enable charging/discharging at an ultrahigh scan rate of 100 V s-1 in a wide voltage window of 1.5 V in Na2SO4 neutral electrolyte. It has an outstanding response time with a characteristic time constant of 4 ms. Significantly, the TiN paper-based SCs also show zero capacitance loss after 200,000 cycles, which is much better than the stability performance reported for other metal nitride SCs. Furthermore, the device shows great promise in scalability. The filtration method enables good control of the thickness and mass loading of TiN electrodes and devices.

Published
2019

13. Recovery of Rare Earth Elements from Geothermal Fluids through Bacterial Cell Surface Adsorption

Author

Brewer, Aaron, Chang, Elliot, Park, Dan M, Kou, Tianyi, Li, Yat, Lammers, Laura N, and Jiao, Yongqin

Subjects
Earth Sciences, Geochemistry, Chemical Sciences, Adsorption, Bacteria, Escherichia coli, Lanthanoid Series Elements, Metals, Rare Earth, Environmental Sciences
Abstract

The increasing demand for rare earth elements (REEs) in the modern economy motivates the development of novel strategies for cost-effective REE recovery from nontraditional feedstocks. We previously engineered E. coli to express lanthanide binding tags on the cell surface, which increased the REE biosorption capacity and selectivity. Here we examined how REE adsorption by the engineered E. coli is affected by various geochemical factors relevant to geothermal fluids, including total dissolved solids (TDS), temperature, pH, and the presence of specific competing metals. REE biosorption is robust to TDS, with high REE recovery efficiency and selectivity observed with TDS as high as 165,000 ppm. Among several metals tested, U, Al, and Pb were found to be the most competitive, causing >25% reduction in REE biosorption when present at concentrations ∼3- to 11-fold higher than the REEs. Optimal REE biosorption occurred between pH 5-6, and sorption capacity was reduced by ∼65% at pH 2. REE recovery efficiency and selectivity increased as a function of temperature up to ∼70 °C due to the thermodynamic properties of metal complexation on the bacterial surface. Together, these data define the optimal and boundary conditions for biosorption and demonstrate its potential utility for selective REE recovery from geofluids.

Published
2019

14. Ni Foam-Supported Fe-Doped β‑Ni(OH)2 Nanosheets Show Ultralow Overpotential for Oxygen Evolution Reaction

Author

Kou, Tianyi, Wang, Shanwen, Hauser, Jesse L, Chen, Mingpeng, Oliver, Scott RJ, Ye, Yifan, Guo, Jinghua, and Li, Yat

Subjects
Affordable and Clean Energy
Abstract

Oxygen evolution reaction (OER) involves multiple electron-transfer processes, resulting in a high activation barrier. Developing catalysts with low overpotential and high intrinsic activity toward OER is critical but challenging. Here we report a major advancement in decreasing the overpotential for oxygen evolution reaction. Ni foam-supported Fe-doped β-Ni(OH) 2 nanosheets achieve an overpotential of 219 mV at the geometric current density of 10 mA cm -2 . To our knowledge, this is the best value reported for Ni- or Fe hydroxide-based OER catalysts. In addition, the catalyst yields a current density of 6.25 mA cm -2 at the overpotential of 300 mV when it is normalized to the electrochemical surface area of the catalyst. This intrinsic catalytic activity is also better than the values reported for most state-of-the-art OER catalysts at the same overpotential.

Published
2019

16. Role of Hydrogen in Defining the n‑Type Character of BiVO4 Photoanodes

Author

Cooper, Jason K, Scott, Soren B, Ling, Yichuan, Yang, Jinhui, Hao, Sijie, Li, Yat, Toma, Francesca M, Stutzmann, Martin, Lakshmi, KV, and Sharp, Ian D

Subjects
Chemical Sciences, Physical Chemistry, Engineering, Materials, Chemical sciences
Abstract

The roles of hydrogen impurity and oxygen vacancy defects on defining the conductivity, and hence photoelectrochemical (PEC) performance characteristics, of monoclinic scheelite bismuth vanadate (BiVO4) are investigated using a combination of experiment and theory. We find that elemental hydrogen is present as an impurity in as-synthesized BiVO4 and that increasing its concentration by annealing in H2 at temperatures up to 290 °C leads to near-complete elimination of majority carrier transport limitations, a beneficial shift in the photoanodic current onset potential, and improved fill factor. Magnetic resonance measurements reveal that hydrogen can be incorporated in at least two different chemical environments, which are assigned to interstitial and substitutional sites. Incorporation of hydrogen leads to a shift of the Fermi level toward the conduction band edge, indicating that n-type character is correlated with increased hydrogen content. This finding is in agreement with theory and reveals that hydrogen acts as a donor in BiVO4. Sub-bandgap photoluminescence is observed from as-synthesized material and is consistent with deep electronic states associated with oxygen vacancies. Hydrogen treatment leads to reduced emission from these states. These findings support the conclusion that hydrogen, rather than oxygen vacancies, is dominant in determining the n-type conductivity of BiVO4. These findings have important implications for controlling the electronic properties and functional characteristics of this promising photoanode material.

Published
2016

17. Organolead Halide Perovskite Nanocrystals: Branched Capping Ligands Control Crystal Size and Stability

Author

Luo, Binbin, Pu, Ying‐Chih, Lindley, Sarah A, Yang, Yi, Lu, Liqiang, Li, Yat, Li, Xueming, and Zhang, Jin Z

Subjects
Chemical Sciences, Physical Chemistry, (3-aminopropyl)triethoxysilane, nanocrystals, nanocrystal stability, organolead halide perovskites, photoluminescence, Organic Chemistry, Chemical sciences
Abstract

CH3 NH3 PbBr3 perovskite nanocrystals (PNCs) of different sizes (ca. 2.5-100 nm) with high photoluminescence (PL) quantum yield (QY; ca. 15-55 %) and product yield have been synthesized using the branched molecules, APTES and NH2 -POSS, as capping ligands. These ligands are sterically hindered, resulting in a uniform size of PNCs. The different capping effects resulting from branched versus straight-chain capping ligands were compared and a possible mechanism proposed to explain the dissolution-precipitation process, which affects the growth and aggregation of PNCs, and thereby their overall stability. Unlike conventional PNCs capped with straight-chain ligands, APTES-capped PNCs show high stability in protic solvents as a result of the strong steric hindrance and propensity for hydrolysis of APTES, which prevent such molecules from reaching and reacting with the core of PNCs.

Published
2016

20. Oxygen deficient α-Fe 2 O 3 photoelectrodes: a balance between enhanced electrical properties and trap-mediated losses

Author

Forster, Mark, Potter, Richard J, Ling, Yichuan, Yang, Yi, Klug, David R, Li, Yat, and Cowan, Alexander J

Subjects
Chemical Sciences
Abstract

Intrinsic doping of hematite through the inclusion of oxygen vacancies (VO) is being increasingly explored as a simple, low temperature route to preparing active water splitting α-Fe2O3-x photoelectrodes. Whilst it is widely accepted that the introduction of VO leads to improved conductivities, little else is verified regarding the actual mechanism of enhancement. Here we employ transient absorption (TA) spectroscopy to build a comprehensive kinetic model for water oxidation on α-Fe2O3-x . In contrast to previous suggestions, the primary effect of introducing VO is to block very slow (ms) surface hole - bulk electron recombination pathways. In light of our mechanistic research we are also able to identify and address a cause of the high photocurrent onset potential, a common issue with this class of electrodes. Atomic layer deposition (ALD) of Al2O3 is found to be particularly effective with α-Fe2O3-x , leading to the photocurrent onset potential shifting by ca. 200 mV. Significantly TA measurements on these ALD passivated electrodes also provide important insights into the role of passivating layers, that are relevant to the wider development of α-Fe2O3 photoelectrodes.

Published
2015

21. Oxygen deficient α-Fe2O3 photoelectrodes: a balance between enhanced electrical properties and trap-mediated losses.

Author

Forster, Mark, Potter, Richard J, Ling, Yichuan, Yang, Yi, Klug, David R, Li, Yat, and Cowan, Alexander J

Subjects
Chemical Sciences
Abstract

Intrinsic doping of hematite through the inclusion of oxygen vacancies (VO) is being increasingly explored as a simple, low temperature route to preparing active water splitting α-Fe2O3-x photoelectrodes. Whilst it is widely accepted that the introduction of VO leads to improved conductivities, little else is verified regarding the actual mechanism of enhancement. Here we employ transient absorption (TA) spectroscopy to build a comprehensive kinetic model for water oxidation on α-Fe2O3-x . In contrast to previous suggestions, the primary effect of introducing VO is to block very slow (ms) surface hole - bulk electron recombination pathways. In light of our mechanistic research we are also able to identify and address a cause of the high photocurrent onset potential, a common issue with this class of electrodes. Atomic layer deposition (ALD) of Al2O3 is found to be particularly effective with α-Fe2O3-x , leading to the photocurrent onset potential shifting by ca. 200 mV. Significantly TA measurements on these ALD passivated electrodes also provide important insights into the role of passivating layers, that are relevant to the wider development of α-Fe2O3 photoelectrodes.

Published
2015

26. (Invited) Graphene-Based Scaffolds for Electrochemical Energy Storage

Author

Chandrasekaran, Swetha, primary, Lin, Dun, additional, Reale Batista, Mariana Desiree, additional, Li, Hanyu, additional, Carleton, Adam, additional, Xue, Xinzhe, additional, Luo, Yunkai, additional, Hu, Bintao, additional, Moran, Bryan, additional, Roy, Thomas, additional, Orme, Christine, additional, Dunn, Bruce S., additional, Li, Yat, additional, and Worsley, Marcus Andre, additional

Published
2023
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29. The critical role of synthesis conditions on small polaron carrier concentrations in hematite—A first-principles study.

Author

Smart, Tyler J., Chen, Mingpeng, Grieder, Andrew C., Urena Baltazar, Valentin, Bridges, Frank, Li, Yat, and Ping, Yuan

Subjects
HEMATITE, CARRIER density, IONIZATION energy, POLARONS, TRANSITION metal oxides, PARTIAL pressure, ENERGY conversion, OXYGEN
Abstract

Achieving highly efficient energy conversion with transition metal oxides necessitates overcoming conductivity limitations due to the formation of small polarons. Detailed understanding of the interplay among intrinsic defects, dopants, and electron polarons can help devise strategies for achieving higher carrier concentrations, therefore improving carrier conductivity. This work employs first-principles calculations to reliably predict electron polaron concentrations in a prominent polaronic oxide, hematite (F e 2 O 3 ), by resolving interactions between charged defects and electron polarons and keeping charge neutrality condition among all charged species. This work addresses that both V O and Fe i can be primary donors in undoped hematite depending on the synthesis conditions, such as synthesis temperature and oxygen partial pressure, despite the fact that V O owns an extremely high ionization energy compared to k B T. Furthermore, from calculations of a plethora of n -type dopants (group IV and V elements), we find that Ti, Ge, Sb, and Nb are able to raise electron polaron concentrations in hematite significantly without considering dopant clustering. However, the magnitude of electron polaron concentration increase would be smaller if the dopant has a high tendency of clustering, such as Ti. We reveal the critical role of synthesis conditions on tuning electron polaron concentrations of both undoped and doped hematite. Our theoretical analysis provides important insights and general design principles for engineering more conductive polaronic oxides. [ABSTRACT FROM AUTHOR]

Published
2021
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34. Design and additive manufacturing of optimized electrodes for energy storage applications

Author

Reale Batista, Mariana Desireé, primary, Chandrasekaran, Swetha, additional, Moran, Bryan D., additional, Salazar de Troya, Miguel, additional, Pinongcos, Anica, additional, Wang, Zhen, additional, Hensleigh, Ryan, additional, Carleton, Adam, additional, Zeng, Manhao, additional, Roy, Thomas, additional, Lin, Dun, additional, Xue, Xinzhe, additional, Beck, Victor A., additional, Tortorelli, Daniel A., additional, Stadermann, Michael, additional, Zheng, Rayne, additional, Li, Yat, additional, and Worsley, Marcus A., additional

Published
2023
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35. Advanced Cathodes for Electrochemical Energy Storage Devices

Author

Lin, Dun, Li, Yat YL1, Lin, Dun, Lin, Dun, Li, Yat YL1, and Lin, Dun

Abstract

The growing awareness of the detrimental effects of fossil fuel consumption on the environment has led to an increased demand for sustainable and clean energy sources worldwide. This has driven the development and application of electrochemical energy storage devices (EESDs), including rechargeable batteries and supercapacitors, in order to better utilize intermittent renewable energy sources such as solar and wind power, and to provide continuous and reliable power supply. The cathodes of EESDs have been found to play a critical role in determining their performance, including specific capacity, output voltage, rate capability, energy/power density, and efficiencies, as well as their calendar life, thermal stability, cost, and environmental impact. Unfortunately, cathodes are still one of the major challenges in the advancements of EESDs. Developing advanced cathodes based on different electrochemical energy storage mechanisms, such as electric double-layer capacitance, pseudocapacitance, bulk ion insertion/desertion, and conversion reactions, has been an important task in order to fulfill the demands of EESDs for different application scenarios.The scope of this dissertation covers the research of my past five years in designing and optimizing different types of cathodes for high-performance EESDs. Chapter one presents the background of EESDs and explains the advances of different types of cathodes for EESDs. Chapter two introduces a 3D printed porous carbon cathode templated by microporous metal-organic framework, which serves as EDLC-type cathodes for aqueous zinc-ion hybrid capacitors with high areal capacitance and energy density. Chapter three focuses on the graded design of a 3D printed graphene aerogel substrate, which improves electrodeposition uniformity and electrochemical accessibility of ultrahigh-loading MnO2 cathode based on lithium-ion insertion/desertion for non-aqueous lithium-ion hybrid capacitors with high volumetric energy density. A double-lay

Published
2023

43. Additive Manufacture of Graphene Electrodes for Supercapacitor Applications

Author

Reale Batista, Mariana Desiree, primary, Chandrasekaran, Swetha, additional, Moran, Bryan, additional, Salazar de Troya, Miguel A, additional, Carleton, Adam, additional, Roy, Thomas, additional, Zeng, Manhao, additional, Pinongcos, Anica, additional, Lin, Dun, additional, Wang, Zhen, additional, Hensleigh, Ryan, additional, Kuntz, Joshua, additional, Beck, Victor A, additional, Tortorelli, Daniel, additional, Stadermann, Michael, additional, Li, Yat, additional, Zheng, Rayne, additional, and Worsley, Marcus Andre, additional

Published
2022
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50. (Invited) 3D Printing of 2D Materials for Optimized Electrochemical Performance

Author

Worsley, Marcus Andre, primary, Beck, Victor A, additional, Reale Batista, Mariana Desiree, additional, Chandrasekaran, Swetha, additional, Moran, Bryan, additional, Salazar de Troya, Miguel A, additional, Carleton, Adam, additional, Roy, Thomas, additional, Tortorelli, Daniel, additional, Stadermann, Michael, additional, Pinongcos, Anica, additional, Lin, Dun, additional, Wang, Zhen, additional, Hensleigh, Ryan, additional, and Li, Yat, additional

Published
2022
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