Your search keyword '"Xin, Huolin L."' showing total 17 results

1. Chemically coupling SnO2 quantum dots and MXene for efficient CO2 electroreduction to formate and Zn–CO2 battery

Author

Han, Lili, Peng, Xianyun, Wang, Hsiao-Tsu, Ou, Pengfei, Mi, Yuying, Pao, Chih-Wen, Zhou, Jigang, Wang, Jian, Liu, Xijun, Pong, Way-Faung, Song, Jun, Lin, Zhang, Luo, Jun, and Xin, Huolin L

Subjects

Chemical Sciences, Physical Chemistry, Engineering, Physical Sciences, Materials Engineering, Affordable and Clean Energy, CO2 reduction reaction, MXene ultrathin nanosheets, SnO2 quantum dot, Zn–CO2 battery

Abstract

Electrochemical conversion of CO2 into formate is a promising strategy for mitigating the energy and environmental crisis, but simultaneously achieving high selectivity and activity of electrocatalysts remains challenging. Here, we report low-dimensional SnO2 quantum dots chemically coupled with ultrathin Ti3C2Tx MXene nanosheets (SnO2/MXene) that boost the CO2 conversion. The coupling structure is well visualized and verified by high-resolution electron tomography together with nanoscale scanning transmission X-ray microscopy and ptychography imaging. The catalyst achieves a large partial current density of -57.8 mA cm-2 and high Faradaic efficiency of 94% for formate formation. Additionally, the SnO2/MXene cathode shows excellent Zn-CO2 battery performance, with a maximum power density of 4.28 mW cm-2, an open-circuit voltage of 0.83 V, and superior rechargeability of 60 h. In situ X-ray absorption spectroscopy analysis and first-principles calculations reveal that this remarkable performance is attributed to the unique and stable structure of the SnO2/MXene, which can significantly reduce the reaction energy of CO2 hydrogenation to formate by increasing the surface coverage of adsorbed hydrogen.

Published

2022

2. An electrochemically stable homogeneous glassy electrolyte formed at room temperature for all-solid-state sodium batteries

Author

Chi, Xiaowei, Zhang, Ye, Hao, Fang, Kmiec, Steven, Dong, Hui, Xu, Rong, Zhao, Kejie, Ai, Qing, Terlier, Tanguy, Wang, Liang, Zhao, Lihong, Guo, Liqun, Lou, Jun, Xin, Huolin L, Martin, Steve W, and Yao, Yan

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy

Abstract

All-solid-state sodium batteries (ASSSBs) are promising candidates for grid-scale energy storage. However, there are no commercialized ASSSBs yet, in part due to the lack of a low-cost, simple-to-fabricate solid electrolyte (SE) with electrochemical stability towards Na metal. In this work, we report a family of oxysulfide glass SEs (Na3PS4-xOx, where 0

Published

2022

3. On the synthesis of bi-magnetic manganese ferrite-based core–shell nanoparticles

Author

Angotzi, Marco Sanna, Mameli, Valentina, Cara, Claudio, Peddis, Davide, Xin, Huolin L, Sangregorio, Claudio, Mercuri, Maria Laura, and Cannas, Carla

Subjects

Engineering, Chemical Sciences, Physical Chemistry, Nanotechnology, Macromolecular and materials chemistry, Materials engineering

Abstract

Multifunctional nano-heterostructures (NHSs) with controlled morphology are cardinal in many applications, but the understanding of the nanoscale colloidal chemistry is yet to be fulfilled. The stability of the involved crystalline phases in different solvents at mid- and high-temperatures and reaction kinetics considerably affect the nucleation and growth of the materials and their final architecture. The formation mechanism of manganese ferrite-based core-shell NHSs is herein investigated. The effects of the core size (8, 10, and 11 nm), the shell nature (cobalt ferrite and spinel iron oxide) and the polarity of the solvent (toluene and octanol) on the dissolution phenomena of manganese ferrite are also studied. Noteworthily, the combined use of bulk (powder X-ray diffraction, 57Fe Mössbauer spectroscopy, and DC magnetometry) and nanoscale techniques (HRTEM and STEM-EDX) provides new insights into the manganese ferrite dissolution phenomena, the colloidal stability in an organic environment, and the critical size below which dissolution is complete. Moreover, the dissolved manganese and iron ions react further, leading to an inverted core-shell in the mother liquor solution, paving the way to novel synthetic pathways in nanocrystal design. The MnFe2O4@CoFe2O4 core-shell heterostructures were also employed as heat mediators, exploiting the magnetic coupling between a hard (CoFe2O4) and a soft phase (MnFe2O4).

Published

2021

4. Hierarchical nickel valence gradient stabilizes high-nickel content layered cathode materials

Author

Lin, Ruoqian, Bak, Seong-Min, Shin, Youngho, Zhang, Rui, Wang, Chunyang, Kisslinger, Kim, Ge, Mingyuan, Huang, Xiaojing, Shadike, Zulipiya, Pattammattel, Ajith, Yan, Hanfei, Chu, Yong, Wu, Jinpeng, Yang, Wanli, Whittingham, M Stanley, Xin, Huolin L, and Yang, Xiao-Qing

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy

Abstract

High-nickel content cathode materials offer high energy density. However, the structural and surface instability may cause poor capacity retention and thermal stability of them. To circumvent this problem, nickel concentration-gradient materials have been developed to enhance high-nickel content cathode materials' thermal and cycling stability. Even though promising, the fundamental mechanism of the nickel concentration gradient's stabilization effect remains elusive because it is inseparable from nickel's valence gradient effect. To isolate nickel's valence gradient effect and understand its fundamental stabilization mechanism, we design and synthesize a LiNi0.8Mn0.1Co0.1O2 material that is compositionally uniform and has a hierarchical valence gradient. The nickel valence gradient material shows superior cycling and thermal stability than the conventional one. The result suggests creating an oxidation state gradient that hides the more capacitive but less stable Ni3+ away from the secondary particle surfaces is a viable principle towards the optimization of high-nickel content cathode materials.

Published

2021

5. Valence-programmable nanoparticle architectures

Author

Sun, Sha, Yang, Shize, Xin, Huolin L, Nykypanchuk, Dmytro, Liu, Mingzhao, Zhang, Honghu, and Gang, Oleg

Subjects

Physical Sciences, Chemical Sciences, Physical Chemistry, Bioengineering, Nanotechnology, Affordable and Clean Energy

Abstract

Nanoparticle-based clusters permit the harvesting of collective and emergent properties, with applications ranging from optics and sensing to information processing and catalysis. However, existing approaches to create such architectures are typically system-specific, which limits designability and fabrication. Our work addresses this challenge by demonstrating that cluster architectures can be rationally formed using components with programmable valence. We realize cluster assemblies by employing a three-dimensional (3D) DNA meshframe with high spatial symmetry as a site-programmable scaffold, which can be prescribed with desired valence modes and affinity types. Thus, this meshframe serves as a versatile platform for coordination of nanoparticles into desired cluster architectures. Using the same underlying frame, we show the realization of a variety of preprogrammed designed valence modes, which allows for assembling 3D clusters with complex architectures. The structures of assembled 3D clusters are verified by electron microcopy imaging, cryo-EM tomography and in-situ X-ray scattering methods. We also find a close agreement between structural and optical properties of designed chiral architectures.

Published

2020

6. Enhancing surface oxygen retention through theory-guided doping selection in Li 1−x NiO 2 for next-generation lithium-ion batteries

Author

Cheng, Jianli, Mu, Linqin, Wang, Chunyang, Yang, Zhijie, Xin, Huolin L, Lin, Feng, and Persson, Kristin A

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Macromolecular and Materials Chemistry, Interdisciplinary Engineering, Macromolecular and materials chemistry, Chemical engineering, Materials engineering

Abstract

Layered lithium metal oxides have become the cathode of choice for state-of-the-art Li-ion batteries (LIBs), particularly those with high Ni content. However, the Ni-rich cathode materials suffer from extensive oxygen evolution, which contributes to the formation of surface rocksalt phases as well as thermal instability. Using first-principles calculations, we systematically evaluate the effectiveness of doping elements to enhance surface oxygen retention of Li1-xNiO2. The evaluation process includes (i) choosing the most stable surface facet from the perspective of equilibrium surface stability analysis of as-synthesized LiNiO2, (ii) determining the preferable atomic site and segregation behavior for each dopant, and (iii) evaluating the surface oxygen retention ability of doped-Li1-xNiO2 (0.25 ≤ x ≤ 1) compared to the pristine material. We also discuss and rationalize the ability of these elements to enhance surface oxygen retention based on local environment descriptors such as dopant-oxygen bond strength. Overall, W, Sb, Ta and Ti are predicted as the most promising surface dopants due to their strong oxygen bonds and robust surface segregation behavior. Finally, Sb-doped LiNiO2 is synthesized and shown to present a surface enrichment of Sb and a significantly improved electrochemical performance, comparing with pristine LiNiO2. This work provides a generic approach that can lead to the greatly enhanced stabilization of all high-energy cathode materials, particularly the high Ni and low Co oxides. This journal is

Published

2020

7. A disordered rock salt anode for fast-charging lithium-ion batteries

Author

Liu, Haodong, Zhu, Zhuoying, Yan, Qizhang, Yu, Sicen, He, Xin, Chen, Yan, Zhang, Rui, Ma, Lu, Liu, Tongchao, Li, Matthew, Lin, Ruoqian, Chen, Yiming, Li, Yejing, Xing, Xing, Choi, Yoonjung, Gao, Lucy, Cho, Helen Sung-yun, An, Ke, Feng, Jun, Kostecki, Robert, Amine, Khalil, Wu, Tianpin, Lu, Jun, Xin, Huolin L, Ong, Shyue Ping, and Liu, Ping

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, General Science & Technology

Abstract

Rechargeable lithium-ion batteries with high energy density that can be safely charged and discharged at high rates are desirable for electrified transportation and other applications1-3. However, the sub-optimal intercalation potentials of current anodes result in a trade-off between energy density, power and safety. Here we report that disordered rock salt4,5 Li3+xV2O5 can be used as a fast-charging anode that can reversibly cycle two lithium ions at an average voltage of about 0.6 volts versus a Li/Li+ reference electrode. The increased potential compared to graphite6,7 reduces the likelihood of lithium metal plating if proper charging controls are used, alleviating a major safety concern (short-circuiting related to Li dendrite growth). In addition, a lithium-ion battery with a disordered rock salt Li3V2O5 anode yields a cell voltage much higher than does a battery using a commercial fast-charging lithium titanate anode or other intercalation anode candidates (Li3VO4 and LiV0.5Ti0.5S2)8,9. Further, disordered rock salt Li3V2O5 can perform over 1,000 charge-discharge cycles with negligible capacity decay and exhibits exceptional rate capability, delivering over 40 per cent of its capacity in 20 seconds. We attribute the low voltage and high rate capability of disordered rock salt Li3V2O5 to a redistributive lithium intercalation mechanism with low energy barriers revealed via ab initio calculations. This low-potential, high-rate intercalation reaction can be used to identify other metal oxide anodes for fast-charging, long-life lithium-ion batteries.

Published

2020

8. Author Correction: Bimetallic synergy in cobalt–palladium nanocatalysts for CO oxidation

Author

Wu, Cheng Hao, Liu, Chang, Su, Dong, Xin, Huolin L, Fang, Hai-Tao, Eren, Baran, Zhang, Sen, Murray, Christopher B, and Salmeron, Miquel B

Subjects

Inorganic Chemistry, Chemical Sciences, Physical Chemistry, Engineering, Chemical Engineering, Inorganic chemistry, Physical chemistry, Chemical engineering

Abstract

In the version of this Article originally published, the author Baran Eren was mistakenly affiliated with the Harbin Institute of Technology, China; it has now been corrected to Materials Science Division, Lawrence Berkeley National Laboratory, Berkeley, CA, USA.

Published

2019

9. Bimetallic synergy in cobalt–palladium nanocatalysts for CO oxidation

Author

Wu, Cheng Hao, Liu, Chang, Su, Dong, Xin, Huolin L, Fang, Hai-Tao, Eren, Baran, Zhang, Sen, Murray, Christopher B, and Salmeron, Miquel B

Subjects

Engineering, Macromolecular and Materials Chemistry, Materials Engineering, Chemical Sciences, Inorganic chemistry, Physical chemistry, Chemical engineering

Abstract

Bimetallic and multi-component catalysts typically exhibit composition-dependent activity and selectivity, and when optimized often outperform single-component catalysts. Here we used ambient-pressure X-ray photoelectron spectroscopy (AP-XPS) and in situ and ex situ transmission electron microscopy (TEM) to elucidate the origin of composition dependence observed in the catalytic activities of monodisperse CoPd bimetallic nanocatalysts for CO oxidation. We found that the catalysis process induced a reconstruction of the catalysts, leaving CoOx on the nanoparticle surface. The synergy between Pd and CoOx coexisting on the surface promotes the catalytic activity of the bimetallic catalysts. This synergistic effect can be optimized by tuning the Co/Pd ratios in the nanoparticle synthesis, and it reaches a maximum at compositions near Co0.24Pd0.76, which achieves complete CO conversion at the lowest temperature. Our combined AP-XPS and TEM studies provide direct observation of the surface evolution of the bimetallic nanoparticles under catalytic conditions and show how this evolution correlates with catalytic properties.

Published

2019

10. Anomalous metal segregation in lithium-rich material provides design rules for stable cathode in lithium-ion battery

Author

Lin, Ruoqian, Hu, Enyuan, Liu, Mingjie, Wang, Yi, Cheng, Hao, Wu, Jinpeng, Zheng, Jin-Cheng, Wu, Qin, Bak, Seongmin, Tong, Xiao, Zhang, Rui, Yang, Wanli, Persson, Kristin A, Yu, Xiqian, Yang, Xiao-Qing, and Xin, Huolin L

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry

Abstract

Despite the importance of studying the instability of delithiated cathode materials, it remains difficult to underpin the degradation mechanism of lithium-rich cathode materials due to the complication of combined chemical and structural evolutions. Herein, we use state-of-the-art electron microscopy tools, in conjunction with synchrotron X-ray techniques and first-principle calculations to study a 4d-element-containing compound, Li2Ru0.5Mn0.5O3. We find surprisingly, after cycling, ruthenium segregates out as metallic nanoclusters on the reconstructed surface. Our calculations show that the unexpected ruthenium metal segregation is due to its thermodynamic insolubility in the oxygen deprived surface. This insolubility can disrupt the reconstructed surface, which explains the formation of a porous structure in this material. This work reveals the importance of studying the thermodynamic stability of the reconstructed film on the cathode materials and offers a theoretical guidance for choosing manganese substituting elements in lithium-rich as well as stoichiometric layer-layer compounds for stabilizing the cathode surface.

Published

2019

11. Structural Degradation of Layered Cathode Materials in Lithium-Ion Batteries Induced by Ball Milling

Author

Pan, Taijun, Alvarado, Judith, Zhu, Jian, Yue, Yuan, Xin, Huolin L, Nordlund, Dennis, Lin, Feng, and Doeff, Marca M

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Macromolecular and Materials Chemistry, Physical Chemistry (incl. Structural), Energy, Physical chemistry, Materials engineering

Abstract

Layered LiNi0.4Mn0.4Co0.18Ti0.02O2 cathode powders were ball-milled for various lengths of time. The structural properties of the pristine and milled powders, which have different particle sizes were examined with X-ray diffraction, soft X-ray absorption spectroscopy, and transmission electron microscopy to determine the effect of milling on structure. Electrochemical testing in halfcells was also carried out and shows that milling plays an important role in the performance of these cathode materials; as milling time increases, there is a decrease in initial discharge capacity. The first cycle irreversible capacity also increases for milled samples, as does capacity loss upon cycling under some regimes.The electrochemical degradation is strongly correlated with damage to the lamellar structure of cathode particles induced by milling, and lithium carbonate formation.

Published

2019

12. Oxygen Release Induced Chemomechanical Breakdown of Layered Cathode Materials

Author

Mu, Linqin, Lin, Ruoqian, Xu, Rong, Han, Lili, Xia, Sihao, Sokaras, Dimosthenis, Steiner, James D, Weng, Tsu-Chien, Nordlund, Dennis, Doeff, Marca M, Liu, Yijin, Zhao, Kejie, Xin, Huolin L, and Lin, Feng

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Cathode, crack, phase transformation, oxygen release, Nanoscience & Nanotechnology

Abstract

Chemical and mechanical properties interplay on the nanometric scale and collectively govern the functionalities of battery materials. Understanding the relationship between the two can inform the design of battery materials with optimal chemomechanical properties for long-life lithium batteries. Herein, we report a mechanism of nanoscale mechanical breakdown in layered oxide cathode materials, originating from oxygen release at high states of charge under thermal abuse conditions. We observe that the mechanical breakdown of charged Li1- xNi0.4Mn0.4Co0.2O2 materials proceeds via a two-step pathway involving intergranular and intragranular crack formation. Owing to the oxygen release, sporadic phase transformations from the layered structure to the spinel and/or rocksalt structures introduce local stress, which initiates microcracks along grain boundaries and ultimately leads to the detachment of primary particles, i.e., intergranular crack formation. Furthermore, intragranular cracks (pores and exfoliations) form, likely due to the accumulation of oxygen vacancies and continuous phase transformations at the surfaces of primary particles. Finally, finite element modeling confirms our experimental observation that the crack formation is attributable to the formation of oxygen vacancies, oxygen release, and phase transformations. This study is designed to directly observe the chemomechanical behavior of layered oxide cathode materials and provides a chemical basis for strengthening primary and secondary particles by stabilizing the oxygen anions in the lattice.

Published

2018

13. Synchrotron X‑ray Analytical Techniques for Studying Materials Electrochemistry in Rechargeable Batteries

Author

Lin, Feng, Liu, Yijin, Yu, Xiqian, Cheng, Lei, Singer, Andrej, Shpyrko, Oleg G, Xin, Huolin L, Tamura, Nobumichi, Tian, Chixia, Weng, Tsu-Chien, Yang, Xiao-Qing, Meng, Ying Shirley, Nordlund, Dennis, Yang, Wanli, and Doeff, Marca M

Subjects

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

Abstract

Rechargeable battery technologies have ignited major breakthroughs in contemporary society, including but not limited to revolutions in transportation, electronics, and grid energy storage. The remarkable development of rechargeable batteries is largely attributed to in-depth efforts to improve battery electrode and electrolyte materials. There are, however, still intimidating challenges of lower cost, longer cycle and calendar life, higher energy density, and better safety for large scale energy storage and vehicular applications. Further progress with rechargeable batteries may require new chemistries (lithium ion batteries and beyond) and better understanding of materials electrochemistry in the various battery technologies. In the past decade, advancement of battery materials has been complemented by new analytical techniques that are capable of probing battery chemistries at various length and time scales. Synchrotron X-ray techniques stand out as one of the most effective methods that allow for nearly nondestructive probing of materials characteristics such as electronic and geometric structures with various depth sensitivities through spectroscopy, scattering, and imaging capabilities. This article begins with the discussion of various rechargeable batteries and associated important scientific questions in the field, followed by a review of synchrotron X-ray based analytical tools (scattering, spectroscopy, and imaging) and their successful applications (ex situ, in situ, and in operando) in gaining fundamental insights into these scientific questions. Furthermore, electron microscopy and spectroscopy complement the detection length scales of synchrotron X-ray tools and are also discussed toward the end. We highlight the importance of studying battery materials by combining analytical techniques with complementary length sensitivities, such as the combination of X-ray absorption spectroscopy and electron spectroscopy with spatial resolution, because a sole technique may lead to biased and inaccurate conclusions. We then discuss the current progress of experimental design for synchrotron experiments and methods to mitigate beam effects. Finally, a perspective is provided to elaborate how synchrotron techniques can impact the development of next-generation battery chemistries.

Published

2017

14. A spongy nickel-organic CO2 reduction photocatalyst for nearly 100% selective CO production

Author

Niu, Kaiyang, Xu, You, Wang, Haicheng, Ye, Rong, Xin, Huolin L, Lin, Feng, Tian, Chixia, Lum, Yanwei, Bustillo, Karen C, Doeff, Marca M, Koper, Marc TM, Ager, Joel, Xu, Rong, and Zheng, Haimei

Subjects

Chemical Engineering, Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy

Abstract

Solar-driven photocatalytic conversion of CO2 into fuels has attracted a lot of interest; however, developing active catalysts that can selectively convert CO2 to fuels with desirable reaction products remains a grand challenge. For instance, complete suppression of the competing H2 evolution during photocatalytic CO2-to-CO conversion has not been achieved before. We design and synthesize a spongy nickel-organic heterogeneous photocatalyst via a photochemical route. The catalyst has a crystalline network architecture with a high concentration of defects. It is highly active in converting CO2 to CO, with a production rate of ~1.6 × 104 μmol hour-1 g-1. No measurable H2 is generated during the reaction, leading to nearly 100% selective CO production over H2 evolution. When the spongy Ni-organic catalyst is enriched with Rh or Ag nanocrystals, the controlled photocatalytic CO2 reduction reactions generate formic acid and acetic acid. Achieving such a spongy nickel-organic photocatalyst is a critical step toward practical production of high-value multicarbon fuels using solar energy.

Published

2017

15. A New Anion Receptor for Improving the Interface between Lithium- and Manganese-Rich Layered Oxide Cathode and the Electrolyte

Author

Ma, Yulin, Zhou, Yan, Du, Chunyu, Zuo, Pengjian, Cheng, Xinqun, Han, Lili, Nordlund, Dennis, Gao, Yunzhi, Yin, Geping, Xin, Huolin L, Doeff, Marca M, Lin, Feng, and Chen, Guoying

Subjects

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

Abstract

Surface degradation on cycled lithium-ion battery cathode particles is governed not only by intrinsic thermodynamic properties of the material but also, oftentimes more predominantly, by the side reactions with the electrolytic solution. A superior electrolyte inhibits these undesired side reactions on the cathode and at the electrolyte interface, which consequently minimizes the deterioration of the cathode surface. The present study investigates a new boron-based anion receptor, tris(2,2,2-trifluoroethyl)borate (TTFEB), as an electrolyte additive in cells containing a lithium- and manganese-rich layered oxide cathode, Li1.16Ni0.2Co0.1Mn0.54O2. Our electrochemical studies demonstrate that the cycling performance and Coulombic efficiency are significantly improved because of the additive, in particular, under elevated temperature conditions. Spectroscopic analyses revealed that the addition of 0.5 wt % TTFEB is capable of reducing the content of lithium-containing inorganic species within the cathode-electrolyte interphase layer and minimizing the reduction of tetravalent Mn4+ at the cathode surface. Our work introduces a novel additive highly effective in improving lithium-ion battery performance, highlights the importance in preserving the surface properties of cathode materials, and provides new insights on the working mechanism of electrolyte additives.

Published

2017

16. Amorphous Lithium Lanthanum Titanate for Solid-State Microbatteries

Author

Lee, Jungwoo Z, Wang, Ziying, Xin, Huolin L, Wynn, Thomas A, and Meng, Ying Shirley

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry, Macromolecular and Materials Chemistry, Physical Chemistry (incl. Structural), Energy, Physical chemistry, Materials engineering

Abstract

Lithium lanthanum titanate (LLTO) is a promising solid state electrolyte for solid state batteries due to its demonstrated high bulk ionic conductivity. However, crystalline LLTO has a relatively low grain boundary conductivity, limiting the overall material conductivity. In this work, we investigate amorphous LLTO (a-LLTO) thin films grown by pulsed laser deposition (PLD). By controlling the background pressure and temperature we are able to optimize the ionic conductivity to 3 × 10-4 S/cm and electronic conductivity to 5 × 10-11 S/cm. XRD, TEM, and STEM/EELS analysis confirm that the films are amorphous and indicate that oxygen background gas is necessary during the PLD process to decrease the oxygen vacancy concentration, decreasing the electrical conductivity. Amorphous LLTO is deposited onto high voltage LiNi0.5Mn1.5O4 (LNMO) spinel cathode thin films and cycled up to 4.8 V vs. Li showing excellent capacity retention. These results demonstrate that a-LLTO has the potential to be integrated into high voltage thin film batteries.

Published

2017

17. Bubble nucleation and migration in a lead–iron hydr(oxide) core–shell nanoparticle

Author

Niu, Kaiyang, Frolov, Timofey, Xin, Huolin L, Wang, Junling, Asta, Mark, and Zheng, Haimei

Subjects

Engineering, Chemical Sciences, Physical Chemistry, Nanotechnology, Bioengineering, bubbles, nucleation, liquid cell, TEM, core-shell nanoparticle, core–shell nanoparticle

Abstract

Iron hydroxide is found in a wide range of contexts ranging from biominerals to steel corrosion, and it can transform to anhydrous oxide via releasing O2 gas and H2O. However, it is not well understood how gases transport through a crystal lattice. Here, we present in situ observation of the nucleation and migration of gas bubbles in iron (hydr)oxide using transmission electron microscopy. We create Pb-FeOOH model core-shell nanoparticles in a liquid cell. Under electron irradiation, iron hydroxide transforms to iron oxide, during which bubbles are generated, and they migrate through the shell to the nanoparticle surface. Geometric phase analysis of the shell lattice shows an inhomogeneous stain field at the bubbles. Our modeling suggests that the elastic interaction between the core and the bubble provides a driving force for bubble migration.

Published

2015