(3 intermediate revisions by one other user not shown)
Line 1: Line 1:
 +
==Abstract==
 +
Coupling between electric and magnetic fields enables smart new devices and may find application in
 +
sensor technology and data storage [<span id='cite-1'></span>[[#1|1]]]. Materials showing magneto-electric (ME) coupling
 +
properties combine two or more ferroic characteristics and are known as multiferroics. Since singlephase
 +
materials show an interaction between polarization and magnetization at very low temperatures
 +
and at the best a too small ME coefficient at room temperature, composite materials become
 +
important. These ME composites consist of magnetically and electrically active phases and generate
 +
the ME coupling as a strain-induced product property. It has to be emphasized that for each of the
 +
two phases the ME coupling modulus is zero and the overall ME modulus is generated by the
 +
interaction between both phases. Here we distinguish between the direct and converse ME effect. The
 +
direct effect characterizes magnetically induced polarization, where an applied magnetic field yields
 +
a deformation of the magneto-active phase which is transferred to the electro-active phase. As a
 +
result, a strain-induced polarization in the electric phase is observed. On the other hand, the converse
 +
effect characterizes electrically activated magnetization. Several experiments on composite
 +
multiferroics showed remarkable ME coefficients that are orders of magnitudes higher than those of
 +
single-phase materials [<span id='cite-2'></span>[[#2|2]]]. Due to the significant influence of the microstructure on the ME effect,
 +
we derived a two-scale finite element (FE<sup>2</sup>) homogenization framework, which allows for the
 +
consideration of microscopic morphologies  [<span id='cite-3'></span>[[#3|3]], <span id='cite-4'></span>[[#4|4]]]. A further major influence on the overall ME
 +
properties is the polarization state of the ferroelectric phase. With this in mind, a material model is
 +
implemented that considers the switching behavior of the spontaneous polarization [<span id='cite-5'></span>[[#5|5]]] and enables a
 +
more exact comparison to experimental measurements in [<span id='cite-6'></span>[[#6|6]]].
 +
 +
== Recording of the presentation ==
 
{| style="font-size:120%; color: #222222; border: 1px solid darkgray; background: #f3f3f3; table-layout: fixed; width:100%;"
 
{| style="font-size:120%; color: #222222; border: 1px solid darkgray; background: #f3f3f3; table-layout: fixed; width:100%;"
|- style="border-bottom: 1px solid darkgray; text-align: center;"
 
| Recording of the presentation
 
 
|-  
 
|-  
 
| {{#evt:service=youtube|id=https://youtu.be/tucxagv9tQ0|alignment=center}}
 
| {{#evt:service=youtube|id=https://youtu.be/tucxagv9tQ0|alignment=center}}
Line 9: Line 30:
 
| Date: 1 - 3 September 2015, Barcelona, Spain.
 
| Date: 1 - 3 September 2015, Barcelona, Spain.
 
|}
 
|}
 
  
 
== General Information ==
 
== General Information ==
 
* Location: Technical University of Catalonia (UPC), Barcelona, Spain.
 
* Location: Technical University of Catalonia (UPC), Barcelona, Spain.
 
* Date: 1 - 3 September 2015
 
* Date: 1 - 3 September 2015
* Secretariat: [//www.cimne.com/ CIMNE] Centre Internacional de Metodes Numerics.
+
* Secretariat: [//www.cimne.com/ International Center for Numerical Methods in Engineering (CIMNE)].
  
 
== External Links ==
 
== External Links ==
 
* [//congress.cimne.com/complas2015/frontal/default.asp Complas XIII] Official Website of the Conference.
 
* [//congress.cimne.com/complas2015/frontal/default.asp Complas XIII] Official Website of the Conference.
 
* [//www.cimnemultimediachannel.com/ CIMNE Multimedia Channel]
 
* [//www.cimnemultimediachannel.com/ CIMNE Multimedia Channel]
 +
 +
==References==
 +
<div id="1"></div>
 +
[[#cite-1|[1]]] N.A. Spalding and M. Fiebig, "The renaissance of magnetoelectric multiferroics", Materials Science, <b>309</b>, 391-392 (2005).
 +
<div id="2"></div>
 +
[[#cite-2|[2]]] M. Fiebig, "Revival of the magnetoelectric effect", Journal of Physics D: Applied Physics, <b>38</b>, R123-R152 (2005).
 +
<div id="3"></div>
 +
[[#cite-3|[3]]] J. Schröder and M.-A. Keip, "Two-scale homogenization of electro-mechanically coupled boundary value problems", Computational Mechanics, <b>50</b>, 229-244 (2012).
 +
<div id="4"></div>
 +
[[#cite-4|[4]]] M. Labusch, M. Etier, D.C. Lupascu, J. Schröder and M.-A Keip, "Product properties of a two-phase magneto-electric composite: Synthesis and numerical modeling", Computational Mechanics, <b>54</b>, 71-83 (2014).
 +
<div id="5"></div>
 +
[[#cite-5|[5]]] S.C. Hwang, C.S. Lynch and R.M. McMeeking, "Ferroelectric/ferroelastic interactions and a polarization switching model", Acta Metall. Mater., <b>43</b>, 2073-2088 (1995).
 +
<div id="6"></div>
 +
[[#cite-6|[6]]] M. Etier, V.V. Shvartsman, Y. Gao, J. Landers, H. Wende and D.C. Lupascu, "Magnetoelectric effect in (0-3) CoFe<sub>2</sub>O<sub>4</sub>-BaTiO<sub>3</sub> (20/80) composite ceramics prepared by the organosol route", Ferroelectrics, <b>448</b>, 77-85 (2013).

Latest revision as of 10:42, 19 July 2016

Abstract

Coupling between electric and magnetic fields enables smart new devices and may find application in sensor technology and data storage [1]. Materials showing magneto-electric (ME) coupling properties combine two or more ferroic characteristics and are known as multiferroics. Since singlephase materials show an interaction between polarization and magnetization at very low temperatures and at the best a too small ME coefficient at room temperature, composite materials become important. These ME composites consist of magnetically and electrically active phases and generate the ME coupling as a strain-induced product property. It has to be emphasized that for each of the two phases the ME coupling modulus is zero and the overall ME modulus is generated by the interaction between both phases. Here we distinguish between the direct and converse ME effect. The direct effect characterizes magnetically induced polarization, where an applied magnetic field yields a deformation of the magneto-active phase which is transferred to the electro-active phase. As a result, a strain-induced polarization in the electric phase is observed. On the other hand, the converse effect characterizes electrically activated magnetization. Several experiments on composite multiferroics showed remarkable ME coefficients that are orders of magnitudes higher than those of single-phase materials [2]. Due to the significant influence of the microstructure on the ME effect, we derived a two-scale finite element (FE2) homogenization framework, which allows for the consideration of microscopic morphologies [3, 4]. A further major influence on the overall ME properties is the polarization state of the ferroelectric phase. With this in mind, a material model is implemented that considers the switching behavior of the spontaneous polarization [5] and enables a more exact comparison to experimental measurements in [6].

Recording of the presentation

Location: Technical University of Catalonia (UPC), Vertex Building.
Date: 1 - 3 September 2015, Barcelona, Spain.

General Information

External Links

References

[1] N.A. Spalding and M. Fiebig, "The renaissance of magnetoelectric multiferroics", Materials Science, 309, 391-392 (2005).

[2] M. Fiebig, "Revival of the magnetoelectric effect", Journal of Physics D: Applied Physics, 38, R123-R152 (2005).

[3] J. Schröder and M.-A. Keip, "Two-scale homogenization of electro-mechanically coupled boundary value problems", Computational Mechanics, 50, 229-244 (2012).

[4] M. Labusch, M. Etier, D.C. Lupascu, J. Schröder and M.-A Keip, "Product properties of a two-phase magneto-electric composite: Synthesis and numerical modeling", Computational Mechanics, 54, 71-83 (2014).

[5] S.C. Hwang, C.S. Lynch and R.M. McMeeking, "Ferroelectric/ferroelastic interactions and a polarization switching model", Acta Metall. Mater., 43, 2073-2088 (1995).

[6] M. Etier, V.V. Shvartsman, Y. Gao, J. Landers, H. Wende and D.C. Lupascu, "Magnetoelectric effect in (0-3) CoFe2O4-BaTiO3 (20/80) composite ceramics prepared by the organosol route", Ferroelectrics, 448, 77-85 (2013).

Back to Top

Document information

Published on 09/06/16
Submitted on 07/06/16

Licence: CC BY-NC-SA license

Document Score

4

Views 312
Recommendations 1

Share this document

claim authorship

Are you one of the authors of this document?