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Автор: Grafiati
Опубліковано: 7 вересня 2023
Оновлено: 18 травня 2024

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1

Despotuli, A. L., and A. V. Andreeva. "Nanoionics - the Developing Informative System. Part. 2. From the First Works to the Current State of Nanoionics Abroad." Nano- i Mikrosistemnaya Tehnika 22, no. 9 (December 29, 2020): 463–84. http://dx.doi.org/10.17587/nmst.22.463-484.

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Анотація:
A critical review presents the stages of formation, development, and current state of nanoionics in Russia and the world. Nanoionics is considered as a developing information system; its history is analyzed in terms of dynamic information theory and in the frame of strategic innovation management. The second part of the review presents in the brief form a panoramic view of nanoionics development abroad. An extended definition of the scientific direction of "nanoionics" is given. Since the foreign literature on the subject of the review is extensive, the results of works in which the term "nanoionics" appears in the title, annotations, and keywords are mainly considered. More detailed analysis is given of the works that have seriously influenced the development of nanoionics and will determine its future. The development of nanoionic devices with memory function, Li-ion batteries, and fuel cells is considered. The important role of the creation of stable interface boundaries in nanoionic devices (on which electrochemical reactions take place) is emphasized. New areas of research such as nanoarchitectonics and iontronics are critically analyzed. On a comparative basis, a scheme for the correct introduction of the new scientific term is proposed.
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2

Schoonman, J. "Nanoionics." Solid State Ionics 157, no. 1-4 (February 2003): 319–26. http://dx.doi.org/10.1016/s0167-2738(02)00228-x.

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3

Despotuli, A. L., and A. V. Andreeva. "Nanoionics - the Developing Informative System. Part. 1. Stages of Formation and Modern State of Nanoionics in Russia." Nano- i Mikrosistemnaya Tehnika 22, no. 8 (October 23, 2020): 403–14. http://dx.doi.org/10.17587/nmst.22.403-414.

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Анотація:
The critical review of stages of formation, development, and modern state of nanoionics in Russia and in the world is presented. The nanoionics is considered as the developing information system; its history is analyzed for the first time in terms of the dynamic theory of information and strategic innovative management. The history stages of beginnings and development of an applied and theoretical nanoionics in Russia are considered in this part of the review. In the main, the results of IMT RAS where researches were carried out for expansion of the nanoionics borders in new directions are analyzed. Results of development of new directions, such as dynamic theory of fast ionic transport (FIT) at a nanoscale (structure-dynamic approach of nanoionics, SDA), and nanoionics of advanced superionic conductors (AdSICs) are presented in more detail. Potential of these directions in breakthrough technologies is discussed.
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4

Despotuli, A. L., and A. V. Andreeva. "Nanoionics - the Developing Informative System. Part 3. Generation of Prognostic Information and the Role of Strategic Innovation Management in the Development of Nanoionics." Nano- i Mikrosistemnaya Tehnika 23, no. 1 (February 24, 2021): 6–23. http://dx.doi.org/10.17587/nmst.23.6-23.

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Анотація:
A critical review of the stages of formation, development, and current state of nanoionics in Russia and in the world is presented. Nanoionics is the science, technology, and application of fast ion transport phenomena in solid-state devices and nanostructures. Nanoionics is considered to be a developing information system, its history is first analyzed in terms of D. S. Chernavskii's dynamic information theory and in the context of the influence of strategic innovation management. In the final part of the review, an in-depth methodological analysis of the evolution of nanoionics in the environment of adjacent disciplines (nanoarchitectonics and iontonics) is performed. The aim of the work is to develop a methodology of scientific knowledge and strategic management. The analysis of nanoionics evolution is carried out in terms of conjuncture and prognostic information, class-subclass relations between attributive spaces of the competing disciplines. It is shown that nanoarchitectonics and iontronics cannot serve as meta-disciplines, because they do not have emergent attributes that are incompatible with the attributes of the discipline "nanotechnology", understood in the broad sense. Also, at present, interface nanoarchitectonics does not generalize nanoionics due to the lack of new attributes in the thesaurus. The results obtained go beyond the relationship of nano-disciplines, as the methodology used is based on the definition of information and addresses the problem of the mechanism of generation of prognostic information.
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5

Kern, Klaus, and Joachim Maier. "Nanoionics and Nanoelectronics." Advanced Materials 21, no. 25-26 (June 24, 2009): 2569. http://dx.doi.org/10.1002/adma.200901896.

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6

DESPOTULI, A., and V. NIKOLAICHIK. "A step towards nanoionics." Solid State Ionics 60, no. 4 (April 1993): 275–78. http://dx.doi.org/10.1016/0167-2738(93)90005-n.

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7

Hasegawa, Tsuyoshi, Kazuya Terabe, Toshitsugu Sakamoto, and Masakazu Aono. "Nanoionics Switching Devices: “Atomic Switches”." MRS Bulletin 34, no. 12 (December 2009): 929–34. http://dx.doi.org/10.1557/mrs2009.215.

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AbstractNovel nanoionics devices, atomic switches, have been developed using a solid-electrochemical reaction to control the formation and annihilation of the metal filament between two electrodes. The switching operation can be achieved simply by the application of a bias voltage to precipitate metal atoms in a nanogap between the two electrodes or to dissolve them onto one of the electrodes. The small size of atomic switches enables rapid switching even though atomic motion is required. They also have several novel characteristics in that they are nonvolatile, consume less power, and have a simple structure and a low on-resistance. Logic gates and 1 kbit nonvolatile memory chips have been developed using atomic switches in order to demonstrate the possibilities for improving present-day electronic devices. Their characteristics also enable the fabrication of new types of electronic devices, such as high-performance programmable logic devices that may achieve a multitude of functions on a single chip.
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8

Yamaguchi, Shu. "Nanoionics—Present and future prospects." Science and Technology of Advanced Materials 8, no. 6 (January 2007): 503. http://dx.doi.org/10.1016/j.stam.2007.10.002.

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9

Despotuli, A. L., and A. V. Andreeva. "Nanoionics: New materials and supercapacitors." Nanotechnologies in Russia 5, no. 7-8 (August 2010): 506–20. http://dx.doi.org/10.1134/s1995078010070116.

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10

Despotuli, A. L., A. V. Andreeva, and B. Rambabu. "Nanoionics of advanced superionic conductors." Ionics 11, no. 3-4 (May 2005): 306–14. http://dx.doi.org/10.1007/bf02430394.

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11

Waser, Rainer, and Masakazu Aono. "Nanoionics-based resistive switching memories." Nature Materials 6, no. 11 (November 2007): 833–40. http://dx.doi.org/10.1038/nmat2023.

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12

Kim, Sangtae, Shu Yamaguchi, and James A. Elliott. "Solid-State Ionics in the 21st Century: Current Status and Future Prospects." MRS Bulletin 34, no. 12 (December 2009): 900–906. http://dx.doi.org/10.1557/mrs2009.211.

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AbstractThe phenomenon of ion migration in solids forms the basis for a wide variety of electrochemical applications, ranging from power generators and chemical sensors to ionic switches. Solid-state ionics (SSI) is the field of research concerning ionic motions in solids and the materials properties associated with them. Owing to the ever-growing technological importance of electrochemical devices, together with the discoveries of various solids displaying superior ionic conductivity at relatively low temperatures, research activities in this field have grown rapidly since the 1960s, culminating in “nanoionics”: the area of SSI concerned with nanometer-scale systems. This theme issue introduces key research issues that we believe are, and will remain, the main research topics in nanoionics and SSI during the 21st century. These include the application of cutting-edge experimental techniques, such as secondary ion mass spectroscopy and nuclear magnetic resonance, to investigate ionic diffusion in both bulk solids and at interfaces, as well as the use of atomic-scale modeling as a virtual probe of ionic conduction mechanisms and defect interactions. We highlight the effects of protonic conduction at the nanometer scale and how better control of interfaces can be employed to make secondary lithium batteries based on nanoionics principles. Finally, in addition to power generation and storage, the emergence of atomic switches based on cation diffusion shows great promise in developing next-generation transistors using SSI.
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13

Lu, Wei, Doo Seok Jeong, Michael Kozicki, and Rainer Waser. "Electrochemical metallization cells—blending nanoionics into nanoelectronics?" MRS Bulletin 37, no. 2 (February 2012): 124–30. http://dx.doi.org/10.1557/mrs.2012.5.

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14

Maier, Joachim. "Nanoionics: ionic charge carriers in small systems." Physical Chemistry Chemical Physics 11, no. 17 (2009): 3011. http://dx.doi.org/10.1039/b902586n.

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15

Maier, J. "Nanoionics: size effects and storage in small systems." Journal of Electroceramics 34, no. 1 (December 22, 2013): 69–73. http://dx.doi.org/10.1007/s10832-013-9886-9.

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16

Waser, Rainer, and Ilia Valov. "Electrochemical Reactions in Nanoionics - Towards Future Resistive Switching Memories." ECS Transactions 25, no. 6 (December 17, 2019): 431–37. http://dx.doi.org/10.1149/1.3206642.

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17

Balakrishna Pillai, Premlal, and Maria Merlyne De Souza. "Nanoionics-Based Three-Terminal Synaptic Device Using Zinc Oxide." ACS Applied Materials & Interfaces 9, no. 2 (January 5, 2017): 1609–18. http://dx.doi.org/10.1021/acsami.6b13746.

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18

Maier, J. "Nanoionics: ion transport and electrochemical storage in confined systems." Nature Materials 4, no. 11 (November 2005): 805–15. http://dx.doi.org/10.1038/nmat1513.

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19

Pervov, V. S., S. I. Ovchinnikova, A. E. Medvedeva, E. V. Makhonina, and N. V. Kireeva. "Nanoionics: Principles of ceramic materials fabrication for electrochemical power generation." Inorganic Materials 52, no. 1 (December 17, 2015): 83–88. http://dx.doi.org/10.1134/s002016851601012x.

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20

Zhan, Hualin, Zhiyuan Xiong, Chi Cheng, Qinghua Liang, Jefferson Zhe Liu, and Dan Li. "Solvation‐Involved Nanoionics: New Opportunities from 2D Nanomaterial Laminar Membranes." Advanced Materials 32, no. 18 (December 23, 2019): 1904562. http://dx.doi.org/10.1002/adma.201904562.

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21

Zhu, Xiaojian, Jiantao Zhou, Lin Chen, Shanshan Guo, Gang Liu, Run-Wei Li, and Wei D. Lu. "In Situ Nanoscale Electric Field Control of Magnetism by Nanoionics." Advanced Materials 28, no. 35 (June 27, 2016): 7658–65. http://dx.doi.org/10.1002/adma.201601425.

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22

Wang, Zhiyong, Laiyuan Wang, Masaru Nagai, Linghai Xie, Mingdong Yi, and Wei Huang. "Nanoionics-Enabled Memristive Devices: Strategies and Materials for Neuromorphic Applications." Advanced Electronic Materials 3, no. 7 (May 12, 2017): 1600510. http://dx.doi.org/10.1002/aelm.201600510.

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23

Lee, Shinbuhm, and Judith L. MacManus-Driscoll. "Research Update: Fast and tunable nanoionics in vertically aligned nanostructured films." APL Materials 5, no. 4 (April 2017): 042304. http://dx.doi.org/10.1063/1.4978550.

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24

Despotuli, Alexandr, and Alexandra Andreeva. "Method of uniform effective field in structure-dynamic approach of nanoionics." Ionics 22, no. 8 (March 10, 2016): 1291–98. http://dx.doi.org/10.1007/s11581-016-1668-3.

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25

Despotuli, Alexandr, and Alexandra Andreeva. "Dimensional factor and reciprocity theorem in structure-dynamic approach of nanoionics." Ionics 24, no. 1 (June 2, 2017): 237–41. http://dx.doi.org/10.1007/s11581-017-2168-9.

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26

Despotuli, A. L., and A. V. Andreeva. "Dimensional Factors and Non-Linear Processes in Structure-Dynamic Approach of Nanoionics." Nano- i Mikrosistemnaya Tehnika 19, no. 6 (June 25, 2017): 338–52. http://dx.doi.org/10.17587/nmst.19.338-352.

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27

Despotuli, Alexandr, and Alexandra Andreeva. "Maxwell displacement current and nature of Jonsher’s “universal” dynamic response in nanoionics." Ionics 21, no. 2 (June 27, 2014): 459–69. http://dx.doi.org/10.1007/s11581-014-1183-3.

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28

Maier, Joachim. "Pushing Nanoionics to the Limits: Charge Carrier Chemistry in Extremely Small Systems." Chemistry of Materials 26, no. 1 (September 30, 2013): 348–60. http://dx.doi.org/10.1021/cm4021657.

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29

Maier, J. "Defect chemistry and ion transport in nanostructured materials Part II. Aspects of nanoionics." Solid State Ionics 157, no. 1-4 (February 2003): 327–34. http://dx.doi.org/10.1016/s0167-2738(02)00229-1.

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30

Sepúlveda, Paulina, Ignacio Muga, Norberto Sainz, René G. Rojas, and Sebastián Ossandón. "Nanoionics from a quantum mechanics point of view: Mathematical modeling and numerical simulation." Computer Methods in Applied Mechanics and Engineering 407 (March 2023): 115926. http://dx.doi.org/10.1016/j.cma.2023.115926.

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31

Wan, Tao, Lepeng Zhang, Haiwei Du, Xi Lin, Bo Qu, Haolan Xu, Sean Li, and Dewei Chu. "Recent Developments in Oxide-Based Ionic Conductors: Bulk Materials, Nanoionics, and Their Memory Applications." Critical Reviews in Solid State and Materials Sciences 43, no. 1 (December 20, 2016): 47–82. http://dx.doi.org/10.1080/10408436.2016.1244657.

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32

Nagata, Takahiro, Masamitsu Haemori, and Toyohiro Chikyow. "Combinatorial Synthesis of Cu/(TaxNb1–x)2O5 Stack Structure for Nanoionics-Type ReRAM Device." ACS Combinatorial Science 15, no. 8 (August 2, 2013): 435–38. http://dx.doi.org/10.1021/co4000425.

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33

Maier, Joachim. "ChemInform Abstract: Pushing Nanoionics to the Limits: Charge Carrier Chemistry in Extremely Small Systems." ChemInform 45, no. 11 (February 27, 2014): no. http://dx.doi.org/10.1002/chin.201411231.

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34

Banerjee, Writam, Seong Hun Kim, Seungwoo Lee, Donghwa Lee, and Hyunsang Hwang. "An Efficient Approach Based on Tuned Nanoionics to Maximize Memory Characteristics in Ag‐Based Devices." Advanced Electronic Materials 7, no. 4 (March 16, 2021): 2100022. http://dx.doi.org/10.1002/aelm.202100022.

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35

Manikandan, J., T. Tsuchiya, M. Takayanagi, K. Kawamura, T. Higuchi, K. Terabe, and R. Jayavel. "Substrate effect on the neuromorphic function of nanoionics-based transistors fabricated using WO3 thin film." Solid State Ionics 364 (June 2021): 115638. http://dx.doi.org/10.1016/j.ssi.2021.115638.

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36

Chen, Yun, Kirk Gerdes, Sergio A. Paredes Navia, Liang Liang, Alec Hinerman, and Xueyan Song. "Conformal Electrocatalytic Surface Nanoionics for Accelerating High-Temperature Electrochemical Reactions in Solid Oxide Fuel Cells." Nano Letters 19, no. 12 (October 31, 2019): 8767–73. http://dx.doi.org/10.1021/acs.nanolett.9b03515.

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37

Nagata, T., Y. Yamashita, H. Yoshikawa, K. Kobayashi, and T. Chikyow. "(Invited) Photoelectron Spectroscopic Study on High-k Dielectrics Based Nanoionics-Type ReRAM Structure under Bias Operation." ECS Transactions 61, no. 2 (March 24, 2014): 301–10. http://dx.doi.org/10.1149/06102.0301ecst.

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38

Lovett, Adam J., Ahmed Kursumovic, Siân Dutton, Zhimin Qi, Zihao He, Haiyan Wang, and Judith L. MacManus-Driscoll. "Lithium-based vertically aligned nancomposite films incorporating LixLa0.32(Nb0.7Ti0.32)O3 electrolyte with high Li+ ion conductivity." APL Materials 10, no. 5 (May 1, 2022): 051102. http://dx.doi.org/10.1063/5.0086844.

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Vertically aligned nanocomposite (VAN) thin films have shown strong potential in oxide nanoionics but are yet to be explored in detail in solid-state battery systems. Their 3D architectures are attractive because they may allow enhancements in capacity, current, and power densities. In addition, owing to their large interfacial surface areas, the VAN could serve as models to study interfaces and solid-electrolyte interphase formation. Here, we have deposited highly crystalline and epitaxial vertically aligned nanocomposite films composed of a LixLa0.32±0.05(Nb0.7±0.1Ti0.32±0.05)O3±δ-Ti0.8±0.1Nb0.17±0.03O2±δ-anatase [herein referred to as LL(Nb, Ti)O-(Ti, Nb)O2] electrolyte/anode system, the first anode VAN battery system reported. This system has an order of magnitude increased Li+ ionic conductivity over that in bulk Li3xLa1/3−xNbO3 and is comparable with the best available Li3xLa2/3−xTiO3 pulsed laser deposition films. Furthermore, the ionic conducting/electrically insulating LL(Nb, Ti)O and electrically conducting (Ti, Nb)O2 phases are a prerequisite for an interdigitated electrolyte/anode system. This work opens up the possibility of incorporating VAN films into an all solid-state battery, either as electrodes or electrolytes, by the pairing of suitable materials.
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39

Matsumoto, Hiroshige, Yoshihisa Furuya, Sachio Okada, Takayoshi Tanji, and Tatsumi Ishihara. "Nanoionics phenomenon in proton-conducting oxide: Effect of dispersion of nanosize platinum particles on electrical conduction properties." Science and Technology of Advanced Materials 8, no. 6 (January 2007): 531–35. http://dx.doi.org/10.1016/j.stam.2007.09.008.

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40

Yang, Rui, Kazuya Terabe, Tohru Tsuruoka, Tsuyoshi Hasegawa, and Masakazu Aono. "Oxygen migration process in the interfaces during bipolar resistance switching behavior of WO3−x-based nanoionics devices." Applied Physics Letters 100, no. 23 (June 4, 2012): 231603. http://dx.doi.org/10.1063/1.4726084.

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41

Kawamura, Kinya, Takashi Tsuchiya, Makoto Takayanagi, Kazuya Terabe та Tohru Higuchi. "Electrical-pulse-induced resistivity modulation in Pt/TiO2−δ/Pt multilayer device related to nanoionics-based neuromorphic function". Japanese Journal of Applied Physics 56, № 6S1 (20 квітня 2017): 06GH01. http://dx.doi.org/10.7567/jjap.56.06gh01.

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42

Takamura, Yasuhiro, Kwati Leonard, and Hiroshige Matsumoto. "Effect of Dispersion of Platinum Nanoparticles in Strontium Zirconate and Strontium Cerate Proton Conductors." ECS Meeting Abstracts MA2018-01, no. 32 (April 13, 2018): 1943. http://dx.doi.org/10.1149/ma2018-01/32/1943.

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Анотація:
The interface of two materials having different work function leads to the development of space charge, resulting in the change of defect equivalence and hence the change in the charge carrier concentration. Another possibility lies in the formation of strain at the interface resulting in the change of the mobility of ionic charge carriers. If we can use these effects for the enhancement of ionic conductivity, introduction of hetero-interface is a potential guideline for designing new ion conduction in solids. We have reported previously that when Pt nanoparticles precipitate in proton conducting SrZr0.9Y0.1O3-δ (SZY), the electrical conductivity decreases markedly due to nanoionics effects; small amount of Pt can be dissolved into the Zr site and becomes zero-valent upon exposure to hydrogen [1]. Such a change in the macroscopic electrochemical properties is considered as a result of the unique microscopic electrochemical properties of the nanoscale space charge layer generated in the vicinity of the interface when the Pt nanoparticles are precipitated [2]. Using electrochemical spectroscopy, SrCe0.95Yb0.05O3-δ (SCYb) and Sr(Zr,Ce,Y)O3 proton conducting oxide thus doped with Pt were investigated with the aim to clarify the effects and mechanism of the Pt/oxide interface on the electrical properties of proton conducting oxide. Pt-doped proton conducting oxides were prepared by combustion synthesis method. The electrical conductivity of Pt-SZY and Pt-SCYb measured at 800 °C under 1% H2 and air atmospheres revealed a reversible nanoionics phenomenon as a result of precipitation and dissolution of platinum nanoparticles (Fig.1). The electrical conductivity then decreases significantly when the atmosphere is change to hydrogen for Pt-SZY. In the case of Pt-SCYb an increase in the conductivity can be seen for the same changes of the atmosphere. This change in electrical conductivity has been explained by the effect of precipitated Pt particles. In other words, a proton deficient region is formed in the vicinity of the interface between Pt and SZY whereas at the interface between Pt and SCYb, there is no such influence. Also, this result can be applied to deepen understanding of the reaction at the electrodes of the electrochemical cell. Comparing the electrode overvoltage when SZY and SCYb are used for the electrolyte in a cell using Pt as the electrode, SZY is several orders of magnitude larger than SCYb [3]. The reason for this can be explained if it is thought that the region where protons are not present is formed near the interface of Pt / SZY like as the case of Pt nanoparticles disperse in the bulk of SZY. On the other hand, the reason why the overvoltage at Pt/SCYb interface is smaller than that at SZY is considered to be a reasonable result of the loss of protons not taking place significantly near the interface. References [1] H. Matsumoto et. al., Solid State Ionics, 182 (2011), p. 13 [2] J. Maier, Nature Materials, 4 (2005), p. 805 [3] H. Matsumoto et. al., J. Alloys Compd. 408–412 (2006), p. 456 Figure 1
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43

Chen, Yun, Cesar O. Romo-De-La-Cruz, Sergio A. Paredes-Navia, Liang Liang, Alec Hinerman, Jacky Prucz, Mark Williams, and Xueyan Song. "Electrocatalytic surface nanoionics with strained interfaced and colossal conductivity for enhancing durability and performance of solid oxide fuel cell." Journal of Power Sources 517 (January 2022): 230715. http://dx.doi.org/10.1016/j.jpowsour.2021.230715.

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44

Yang, Rui, Kazuya Terabe, Yiping Yao, Tohru Tsuruoka, Tsuyoshi Hasegawa, James K. Gimzewski, and Masakazu Aono. "Synaptic plasticity and memory functions achieved in a WO3−x-based nanoionics device by using the principle of atomic switch operation." Nanotechnology 24, no. 38 (September 2, 2013): 384003. http://dx.doi.org/10.1088/0957-4484/24/38/384003.

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45

Matsumoto, Hiroshige, Takayoshi Tanji, Koji Amezawa, Tatsuya Kawada, Yoshiharu Uchimoto, Yoshihisa Furuya, Takaaki Sakai, Maki Matsuka, and Tatsumi Ishihara. "Nanoprotonics in perovsikte-type oxides: Reversible changes in color and ion conductivity due to nanoionics phenomenon in platinum-containing perovskite oxide." Solid State Ionics 182, no. 1 (February 3, 2011): 13–18. http://dx.doi.org/10.1016/j.ssi.2010.11.016.

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46

Islam, Mohammad, Jared Bouldin, Junghoon Yang, and Sang-Don Han. "(Digital Presentation) Electrochemical Sodiation Mechanism in Magnetite Nanoparticle-Based Anodes: Understanding of Nanoionics-Based Sodium Ion Storage Behavior of Fe3O4." ECS Meeting Abstracts MA2022-02, no. 7 (October 9, 2022): 2430. http://dx.doi.org/10.1149/ma2022-0272430mtgabs.

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Анотація:
Electrochemical ion storage behaviors of Fe3O4 nanoparticles, as a representative transition metal oxide for an environmentally benign and low cost anode for a sodium ion battery, are thoroughly investigated through a combination of electrochemical analysis and diagnostics of Fe3O4 electrode cells, X-ray based and spectroscopic analysis of material structure evolution as functions of depth of discharge (DoD) and state of charge (SoC), and first principle modeling. The gravimetric capacity is found to be 50 mAh/g for bulk Fe3O4 (50 nm average crystallite size) and 100 mAh/g—about a tenth of the theoretical prediction for complete conversion—for Fe3O4 nanoparticles (8.7 nm average particle size), respectively. A fundamental and mechanistic study of material evolution as functions DoD and SoC shows that Fe3O4 does not allow electrochemical incorporation of Na+ ions into the empty cation positions of the inverse spinel structure, leading to our assertion that electrochemical intercalation of Na+ ions to conversion of Fe3O4 anode in sodium ion batteries is nonviable. Density Functional Theory investigation points to the impracticality of the intercalation of Na+ ions into Fe3O4, and further validates our experimental findings. We propose several possible mechanisms corresponding to the observed low capacity, including formation of solid electrolyte interphases with unfavorable properties, adsorption of Na+ ions onto surfaces of nanoparticles and/or at hetero-interfaces in Fe3O4 composite electrodes in a NaPF6-based electrolyte system.
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47

DESPOTULI, ALEXANDER, and ALEXANDRA ANDREEVA. "A SHORT REVIEW ON DEEP-SUB-VOLTAGE NANOELECTRONICS AND RELATED TECHNOLOGIES." International Journal of Nanoscience 08, no. 04n05 (August 2009): 389–402. http://dx.doi.org/10.1142/s0219581x09006328.

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Анотація:
The decrease of energy consumption per 1 bit processing (ε) and power supply voltage (V dd ) of integrated circuits (ICs) are long-term tendencies in micro- and nanoelectronics. In this framework, deep-sub-voltage nanoelectronics (DSVN), i.e., ICs of ~1011–1012 cm-2 component densities operating near the theoretical limit of ε, is sure to find application in the next 10 years. In nanoelectronics, the demand on high-capacity capacitors of micron sizes sharply increases with a decrease of technological norms, ε and V dd . Creation of high-capacity capacitors of micron size to meet the challenge of DSVN and related technologies is considered. The necessity of developing all-solid-state impulse micron-sized supercapacitors on the basis of advanced superionic conductors (nanoionic supercapacitors) is discussed. Theoretical estimates and experimental data on prototype nanoionic supercapacitors with capacity density δC ≈ 100 μF/cm2 are presented. Future perspectives of nanoionic devices are briefly discussed.
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48

Zhu, Xiaojian, Seung Hwan Lee, and Wei D. Lu. "Nanoionic Resistive‐Switching Devices." Advanced Electronic Materials 5, no. 9 (May 20, 2019): 1900184. http://dx.doi.org/10.1002/aelm.201900184.

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49

Bagdzevicius, Sarunas, Michel Boudard, José Manuel Caicedo, Laetitia Rapenne, Xavier Mescot, Raquel Rodríguez-Lamas, Florence Robaut, Jose Santiso, and Mónica Burriel. "Superposition of interface and volume type resistive switching in perovskite nanoionic devices." Journal of Materials Chemistry C 7, no. 25 (2019): 7580–92. http://dx.doi.org/10.1039/c9tc00609e.

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50

CHADWICK, A., and S. SAVIN. "Structure and dynamics in nanoionic materials." Solid State Ionics 177, no. 35-36 (November 30, 2006): 3001–8. http://dx.doi.org/10.1016/j.ssi.2006.07.046.

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