Medidas diretas do efeito magnetocalórico convencional e anisotrópico por medida do fluxo de calor com dispositivos Peltier / Direct measurement of the convencional and anisotropic magnetocaloric effect by heat flux measurements with Peltier devices

Monteiro, José Carlos Botelho, 1984-

30 August 2018

Orientador: Flávio César Guimarães Gandra / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-08-30T17:33:36Z (GMT). No. of bitstreams: 1 Monteiro_JoseCarlosBotelho_D.pdf: 10216375 bytes, checksum: 06d25402d8c5828939f2e7fa0710efbe (MD5) Previous issue date: 2016 / Resumo: Esta tese tem como principal objetivo desenvolver, apresentar e justificar a utilização de uma metodologia experimental que permita avaliar o efeito magnetocalórico (EMC), em qualquer tipo de material, de modo que as medidas reflitam a resposta real que a amostra fornece ao ser submetida a ciclos de magnetização similares àqueles que ocorrem em sistemas de refrigeração magnética. Para tal, construímos sistemas de medidas que utilizam dispositivos Peltier como sensores de fluxo de calor, capazes de realizar medidas diretas da quantidade de calor que a amostra absorve ou libera em situações aonde há variação de temperatura, campo magnético ou do ângulo entre direção do cristal e o campo aplicado. Na primeira parte do trabalho, foram realizadas medidas no sistema com dispositivos Peltier desenvolvido para uso no equipamento comercial PPMS - Physical Property Measurement System (Sistema de medidas de propriedades físicas) da Quantum Design. Utilizamos os métodos indiretos de medida do EMC mais comuns na literatura (medidas via curvas de magnetização e calor específico) para comparação com as medidas diretas de fluxo de calor através de varredura de campo obtidas pelo nosso sistema. Esta análise foi feita inicialmente em duas amostras com transições magnéticas de primeira e segunda ordem, consideradas como amostras padrão na área do EMC: Gadolínio e a liga Gd5Ge2Si2. Discutimos as diferenças encontradas e definimos aquele que acreditamos ser o protocolo de medidas mais correto para a avaliação do EMC para fins práticos. A partir desta conclusão, analisamos três outras amostras que apresentam comportamentos não usuais e alto potencial magnetocalórico e discutimos as diferenças. Perdas do EMC por histerese foram obtidas experimentalmente. Na segunda parte, com o auxílio de um calorímetro com o elemento Peltier capaz de realizar um giro de até 80° sob campo constante de até 1,9 T, realizamos o estudo do efeito magnetocalórico anisotrópico (EMC-ani) em amostras monocristalinas da família RAl2, obtidas pelo processo de Czochralski. Primeiramente medidas de calor específico e do EMC convencional foram realizadas nos monocristais, através do protocolo definido como ideal na primeira parte do trabalho, utilizando o sistema Peltier do PPMS. A partir desses dados, fomos capazes de obter o EMC-ani, de modo indireto, pela subtração das curvas obtidas. Por fim utilizamos o sistema Peltier de giro para realizar medidas diretas do EMC-ani em monocristais de DyAl2. Os resultados das medidas indiretas e diretas foram comparados com cálculos obtidos através de um modelo autoconsistente / Abstract: This thesis aimed to develop, present and justify the use of a methodology that allows one to evaluate the magnetocaloric effect (MCE), for any kind of material, such that the results reflects the real behavior of the sample submitted to magnetization cycles similar to those of magnetic refrigeration systems. To do so, we built measurement systems that uses Peltier devices as heat flux sensors to determine the heat absorbed or released by the sample in situations where the temperature, magnetic field, or angle between a given crystal direction and field changes. In the first part of the work, we report measurements using a Peltier device system developed for use with the Quantum Design PPMS (Physical Property Measurement System). We evaluated the indirect MCE measurements by using the most common techniques found in literature (through magnetization or specific heat curves) and compared to the direct heat flux measurements obtained through field sweep scans with our system. This analysis was initially made with two samples that present a first and a second order magnetic transition, considered as standard samples at MCE research area: Gadolinium and the Gd5Ge2Si2 alloy. We discussed the differences found and defined the measurement protocol that we believe to be correct to the practical evaluation of the MCE. From this conclusion, we analyzed three other samples that present uncommon behavior and high magnetocaloric potential and discussed their differences. MCE hysteresis losses were experimentally obtained. In the second part, with the aid of a calorimeter built with Peltier devices capable of perform an 80° rotation under constant magnetic field up to 1,9 T, we made the study of the Anisotropic Magnetocaloric Effect (MCE-ani) in monocrystalline samples of the RAl2 family grown by the Czochralski method. First, we made specific heat and conventional MCE measurements with the ideal protocol that was defined in the first part of the work, using the PPMS Peltier system. From these data, we were able to calculate indirectly the MCE-ani by subtracting the acquired curves. Finally, we used the Peltier rotation system to perform direct measurements of the MCE-ani in DyAl2 single crystals. The results of the indirect and direct measurements were compared with calculations achieved using a self-consistent process / Doutorado / Física / Doutor em Ciências / 1060137/2011 / CAPES

Efeito magnetocalórico

Efeito magnetocalórico anisotrópico

Intermetálicos de terras raras

Monocristais - Propriedades magnéticas

Histerese

Magnetocaloric effect

Anisotropic magnetocaloric effect

Rare-earth intermetallic compounds

Single crystals - Magnetic properties

Hysteresis

Induced magnetoelectric coupling at a ferroelectric-ferromagnetic interface

Carvell, Jeffrey David

08 November 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Preparation and characterization of multiferroic materials in which ferroelectricity and ferromagnetism coexist would be a milestone for functionalized materials and devices. First, electric properties of polyvinylidene (PVDF) films fabricated using the Langmuir-Schaefer method have been studied. Films of different thickness were deposited on silicon substrates and analyzed using several techniques. X-ray diffraction (XRD) data showed that PVDF films crystallize at an annealing temperature above 130 °C. Polarization versus electric field (PE) ferroelectric measurements were done for samples prepared with electrodes. PE measurements show that the coercivity of the films increases as the maximum applied electric field increases. The coercivity dependence on the frequency of the applied electric field can be fitted as . The results also show that the coercivity decreases with increasing the thickness of PVDF film due to the pinning effect. Next, we have demonstrated that those PVDF properties can be controlled by applying an external magnetic field. Samples were created in a layered heterostructure, starting with a Fe thin film, PVDF above that, and followed by another thin film of Fe. Extended X-ray absorption fine structure (EXAFS) spectroscopy was used to study the interface between PVDF polymer films and ferromagnetic iron thin films. Conventional EXAFS was applied to identify the structure of a Fe film sandwiched between two PVDF layers. An electric signal was then applied to the polymer to study the effects polarizing the polymer has on the Fe atoms at the interface. This shows that the Fe atoms diffuse into the PVDF layer at the interface between the two layers. Polarizing the film causes further diffusion of Fe atoms into the polymer. We also found that as the applied magnetic field is changed, the switching of electric polarization for the PVDF displayed a dependence on the external magnetic field. We also noticed that both the coercivity and polarization for the PVDF polymer display hysteretic features as the applied magnetic field is changed. We also found that the thickness of both the iron layers and the PVDF layer has an effect on the magnetoelectric coupling in our samples. The same strain applied to a thicker PVDF layer becomes tougher to flip the polarization compared to a thinner PVDF layer. As the iron film thickness increases, the strain also increases, and the polarization of the PVDF polymer is more easily flipped. We also found that the magnetoelectric sensitivity increases as both the PVDF and iron layers increase in thickness. We have shown that it is possible to control the ferroelectric properties of a PVDF film by tuning the magnetic field in a heterostructure. Our experiments show a coupling between the electric polarization and applied magnetic field in multiferroic heterostructures much larger than any previously reported values. Previous reports have used inorganic materials for the ferroelectric layer. Organic polymers have an electric dipole originating at the molecular level due to atoms with different electronegativity that are free to rotate. To flip the polarization, the chains must rotate and the position of the atoms must change. This increases the force felt locally by those chains. Using this polymer, we are able to increase the magnetoelectric coupling.

Ferroelectricity -- Research

Ferromagnetic materials -- Analysis

Nanostructured materials

X-rays -- Diffraction

X-ray crystallography

Conducting polymers

Crystals -- Magnetic properties

Crystals -- Electric properties

Heterostructures

Spectrum analysis

Thin films -- Electric properties

Thin films -- Magnetic properties