Toward Controlling Filament Size and Location for Resistive Switches via Nanoparticle Exsolution at Oxide Interfaces

Spring, Jonathan; Sediva, Eva; Hood, Zachary D.; Gonzalez‐Rosillo, Juan Carlos; O’Leary, Willis; Kim, Kun Joong; Carrillo, Alfonso J.; Rupp, Jennifer L. M.

doi:10.1002/smll.202003224

Cited by 32 publications

(38 citation statements)

References 64 publications

(91 reference statements)

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“…After the exsolution treatment (5%H 2 , 900 ºC, 2h) exRuCeO 2 material, the main peak shifted to 769 ºC. Interestingly, when increasing the exsolution treatment up to 5h (Fig.3c) the nanoparticles size increase, as previously observed in Ni exsolution in perovskites, 47,48 and grow solely in the edges of the oxide particles, which progressively change from a rounded-like shape into a 12 metal state, corroborating that the exsolved nanoparticles observed by SEM ( Fig.3) and TEM ( Fig.4) are solely composed by Ru metal. XPS analysis of Ce3d core-level spectra are depicted in Fig.…”

Section: Resultssupporting

confidence: 77%

Boosting methane partial oxidation on ceria through exsolution of robust Ru nanoparticles

et al. 2021

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Section: Resultssupporting

confidence: 77%

Boosting methane partial oxidation on ceria through exsolution of robust Ru nanoparticles

et al. 2021

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“…For instance, in the work of Du et al, they obtained FeNi 3 exsolution from Sr 2 FeMo 0.65 Ni 0.35 O 6−δ after 10 h of treatment in pure H 2 [22]. Increased exposure times and higher H 2 concentrations, as performed by Du et al compared to our work, commonly resulted in larger particle sizes [34,35]. Formation of larger particles could eventually ease their detection by XRD, and, thus the identification of the actual alloy composition of the exsolved nanoparticles.…”

Section: Understanding Fe-ni Alloy Exsolution On Sr 2 Fe X Ni 1-x Moo 6-δsupporting

confidence: 56%

“…This characteristic anchoring, typical of nanoparticle exsolution, avoids sintering with neighboring particles due to the high degree of attachment of the nanoparticles to the oxide surface. Figure 4b-f shows the HAADF-STEM image and EDX mapping of An alternative way to tune the particle size in exsolution is with temperature [12,34,35,38]. In order to explore this aspect, we treated the double layer perovskite mate- An alternative way to tune the particle size in exsolution is with temperature [12,34,35,38].…”

Section: Understanding Fe-ni Alloy Exsolution On Sr 2 Fe X Ni 1-x Moo 6-δmentioning

confidence: 99%

“…Figure 4b-f shows the HAADF-STEM image and EDX mapping of An alternative way to tune the particle size in exsolution is with temperature [12,34,35,38]. In order to explore this aspect, we treated the double layer perovskite mate- An alternative way to tune the particle size in exsolution is with temperature [12,34,35,38]. In order to explore this aspect, we treated the double layer perovskite materials at 700 and 800 °C and compared them with the original exsolution temperature, 900 An alternative way to tune the particle size in exsolution is with temperature [12,34,35,38].…”

Section: Understanding Fe-ni Alloy Exsolution On Sr 2 Fe X Ni 1-x Moo 6-δmentioning

confidence: 99%

“…In order to explore this aspect, we treated the double layer perovskite mate- An alternative way to tune the particle size in exsolution is with temperature [12,34,35,38]. In order to explore this aspect, we treated the double layer perovskite materials at 700 and 800 °C and compared them with the original exsolution temperature, 900 An alternative way to tune the particle size in exsolution is with temperature [12,34,35,38]. In order to explore this aspect, we treated the double layer perovskite materials at 700 and 800 • C and compared them with the original exsolution temperature, 900 • C. As observed in Figure 6a, there were remarkable differences on the exsolved nanoparticle sizes when lowering the temperature.…”

Section: Understanding Fe-ni Alloy Exsolution On Sr 2 Fe X Ni 1-x Moo 6-δmentioning

confidence: 99%

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Exploring the Stability of Fe–Ni Alloy Nanoparticles Exsolved from Double-Layered Perovskites for Dry Reforming of Methane

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Exsolution is emerging as a promising route for the creation of nanoparticles that remain anchored to the oxide support, imparting remarkable stability in high temperature chemical processes such as dry reforming of methane. This process takes place at temperatures around 850 °C, which causes sintering-related issues in catalysts prepared using conventional impregnation methods, which could be overcome by using exsolution functionalized oxides. In this work, FeNi3 alloy nanoparticles exsolved from Sr2FexNi1-xMoO6-δ double-layered perovskites were evaluated as a dry reforming catalyst, paying special attention to structure–activity relationships. Our results indicate that increasing the Ni content favors the nanoparticle dispersion, eventually leading to increased CO2 and CH4 conversions. The exsolved nanoparticles presented remarkable nanoparticle size (ca. 30 nm) stability after the 10 h treatment, although the formation of some phase segregations over the course of the reaction caused a minor decrease in the nanoparticle population. Overall, the results presented here serve as materials processing guidelines that could find further potential use in the design of more efficient (electro)catalysts in other fuel production or energy conversion technologies.

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Resistive Switching by Percolative Conducting Filaments in Organometal Perovskite Unipolar Memory Devices Analyzed Using Current Noise Spectra

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et al. 2021

Adv Funct Materials

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Organometal halide perovskites have emerged as potential material systems for resistive memory devices besides their outstanding optical and electrical properties. Although halide-perovskite resistive memory has the advantage of operating with a low voltage and large on/off ratio, random distribution in operation voltage remains a challenge in memory application. This stochastic operation characteristic is due to the random formation of conducting filaments that cause resistance fluctuations in the material. Therefore, it is essential to investigate the formation and dissolution of conducting filaments and their structure. However, direct observation of a nanoscale filamentary structure is often challenging. Moreover, detailed studies of conducting filaments in halide-perovskite materials have rarely been reported. By employing a scaling theory with a fractal structure, this study investigates the geometric structures and dynamics of conducting filaments formed in organometal halide perovskite through current noise analysis. The temperature-dependent electrical properties and current noise demonstrate the role of ion migration in the formation of conducting filaments. The findings could enhance the understanding of the resistive switching phenomena of perovskite resistive memory devices in terms of percolative conducting filaments. Thus, providing a route for achieving a stable memory operation by controlling the relevant structure and dynamics of the switching processes.

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Toward Controlling Filament Size and Location for Resistive Switches via Nanoparticle Exsolution at Oxide Interfaces

Cited by 32 publications

References 64 publications

Boosting methane partial oxidation on ceria through exsolution of robust Ru nanoparticles

Boosting methane partial oxidation on ceria through exsolution of robust Ru nanoparticles

Exploring the Stability of Fe–Ni Alloy Nanoparticles Exsolved from Double-Layered Perovskites for Dry Reforming of Methane

Resistive Switching by Percolative Conducting Filaments in Organometal Perovskite Unipolar Memory Devices Analyzed Using Current Noise Spectra

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