Specific core-shell approaches and related properties in nanostructured ferroelectric ceramics

Elissalde, Catherine; Chung, U‐Chan; Roulland, F.; Berthelot, Romain; Artemenko, Alla; Majimel, Jérôme; Basov, Sergey; Piraux, Luc; Nysten, Bernard; Mornet, Stéphane; Aymonier, Cyril; Estournès, Claude; Maglione, Mario

doi:10.1080/00150193.2018.1499408

Cited by 6 publications

(6 citation statements)

References 87 publications

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“…Frontiers in Bioengineering and Biotechnology frontiersin.org 2016a; Elissalde et al, 2018). In fact, when the magnetostrictive and the piezoelectric phases are tightly bonded, the strain generated in the core homogenously transfers to the shell, thus more efficiently triggering the electrical field generation.…”

Section: Resultsmentioning

confidence: 99%

Magnetoelectric nanoparticles shape modulates their electrical output

Marrella,

Suarato,

Fiocchi

et al. 2023

Front. Bioeng. Biotechnol.

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Core-shell magnetoelectric nanoparticles (MENPs) have recently gained popularity thanks to their capability in inducing a local electric polarization upon an applied magnetic field and vice versa. This work estimates the magnetoelectrical behavior, in terms of magnetoelectric coupling coefficient (αME), via finite element analysis of MENPs with different shapes under either static (DC bias) and time-variant (AC bias) external magnetic fields. With this approach, the dependence of the magnetoelectrical performance on the MENPs geometrical features can be directly derived. Results show that MENPs with a more elongated morphology exhibits a superior αME if compared with spherical nanoparticles of similar volume, under both stimulation conditions analyzed. This response is due to the presence of a larger surface area at the interface between the magnetostrictive core and piezoelectric shell, and to the MENP geometrical orientation along the direction of the magnetic field. These findings pave a new way for the design of novel high-aspect ratio magnetic nanostructures with an improved magnetoelectric behaviour.

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Section: Resultsmentioning

confidence: 99%

Magnetoelectric nanoparticles shape modulates their electrical output

Marrella,

Suarato,

Fiocchi

et al. 2023

Front. Bioeng. Biotechnol.

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“…They can be located either directly in contact with the powder or between the rams and punches [58]. Alumina powders were also used to prevent ferroelectric ceramics from chemical reduction during SPS [16] and to prevent the pistons of the deforming copper spiral extremities in the co-sintering of transformers for power electronics [59]. Alumina powder placed on both sides of ZnO samples were also used to insulate ZnO from the current.…”

Section: Sacrificial/protective Materials Approaches Combined With Spark Plasma Sinteringmentioning

confidence: 99%

“…In the second part of this paper, original approaches targeting bulk ceramic and thick-film ceramic MEMS produced using advanced sintering techniques associated with protective layers are introduced. While sacrificial materials have already been shown to act as a pore forming agent or as a thermal or diffusion barrier for bulk ceramics [15,16], carbonate based protective materials have recently appeared to efficiently prevent PZT from chemical reduction during spark plasma sintering (SPS) [17]. Chemistry, microstructure, and stress/strain effects are again issues strongly linked to sintering and whose control has an impact on the performance of the electroactive multilayer.…”

Section: Introductionmentioning

confidence: 99%

The Role of Sacrificial and/or Protective Layers to Improve the Sintering of Electroactive Ceramics: Application to Piezoelectric PZT-Printed Thick Films for MEMS

et al. 2020

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Piezoelectric thick films are of real interest for devices such as ceramic Micro-ElectroMechanical Systems (MEMS) because they bridge the gap between thin films and bulk ceramics. The basic design of MEMS includes electrodes, a functional material, and a substrate, and efforts are currently focused on simplified processes. In this respect, screen-printing combined with a sacrificial layer approach is attractive due to its low cost and the wide range of targeted materials. Both the role and the nature of the sacrificial layer, usually a carbon or mineral type, depend on the process and the final device. First, a sacrificial layer method dedicated to screen-printed thick-film ceramic and LTCC MEMS is presented. Second, the recent processing of piezoelectric thick-film ceramic MEMS using spark plasma sintering combined with a protective layer approach is introduced. Whatever the approach, the focus is on the interdependent effects of the microstructure, chemistry, and strain/stress, which need to be controlled to ensure reliable and performant properties of the multilayer electroceramics. Here the goal is to highlight the benefits and the large perspectives of using sacrificial/protective layers, with an emphasis on the pros and cons of such a strategy when targeting a complex piezoelectric MEMS design.

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“…Alumina powders were also used to prevent ferroelectric ceramics from chemical reduction during SPS sintering (Elissalde et al, 2018) and to prevent the pistons of deforming copper spiral extremities in SPS co-sintering of transformers for power electronics (Mercier et al 2016).…”

Section: Iv121 State Of the Artmentioning

confidence: 99%

One step densification of printed multilayers by SPS: Towards new piezoelectric energy harvester MEMS

Debéda

Rua-Taborda

Chung

et al. 2019

Spark Plasma Sintering

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Autonomous electronic devices and increasing use of wireless sensors, which are more and more performant, are facing the problem of energy autonomy. This autonomy can be managed either with a preliminary storage and/or energy harvesting. Hence, since 20 years, the energy harvesting research field is intensive focusing on the development of new materials and their integration in micro/nanogenerators. In this research area, Micro-Electromechanical System (MEMS) energy harvesters (EH) using piezoelectric materials is one of the most promising option because of the availability of mechanical vibrations and of the simply electromechanical conversion. Piezoelectric ceramics, commonly used in various applications, are attractive for EH, and among them, Pb(Zr 1x Ti x)O 3 (PZT), despite its lead content, remains mostly studied because of its outstanding properties. For its ceramic process, the main objectives are improved densification, a cost and energy effective processing and integration in microgenerators. In this context, SPS sintering of electroded printed PZT piezoelectric layers supported on stainless steel substrate (SS) is highly challenging. In this chapter, after a section devoted to piezoelectric EH, the device made of screen-printed PZT layers on SS substrate is presented. Then, the authors focus on the strategy to achieve in one step a cantilever transducer where the electroded printed PZT and the SS substrate are co-sintered by SPS. As a first part of this ambitious objective, microstructural, dielectric and piezoelectric properties of the PZT pellet densified by SPS are presented and compared to PZT printed layers conventionally sintered.

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Specific core-shell approaches and related properties in nanostructured ferroelectric ceramics

Cited by 6 publications

References 87 publications

Magnetoelectric nanoparticles shape modulates their electrical output

Magnetoelectric nanoparticles shape modulates their electrical output

The Role of Sacrificial and/or Protective Layers to Improve the Sintering of Electroactive Ceramics: Application to Piezoelectric PZT-Printed Thick Films for MEMS

One step densification of printed multilayers by SPS: Towards new piezoelectric energy harvester MEMS

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