Ferroelastic domain switching behaviour in lead zirconate titanate under mechanical and electrical loading

Imlao, Soodkhet Bond, Materials Science & Engineering, Faculty of Science, UNSW

January 2008

In this thesis, ferroelastic domain switching behaviour of lead zirconate titanate ceramics, as used in devices such as actuators, was studied. In particular, the effect of cyclic frequency and amplitude were assessed to develop a correlation between macrostructural changes and fatigue behaviour, both in the bulk and in crack-tip process zones. A variety of experimental methods were used. Raman scattering enabled the poling state of the ceramics can be determined. However, it could not distinguish between the different preferred orientations of in-plane c-domains. Conversely, neutron and X-ray diffraction technique can detect domain orientation distribution and the preferred direction of c-domains. In this study, neutron diffraction was used to probe domain switching behaviour in bulk samples while high spatial resolution X-rays were employed to analyse a switching zone near a crack tip. Under cyclic mechanical loading, domain switching and the accumulation of ferroelastic strain becomes saturated with increasing number of cycles. Moreover, time-dependent deformation was investigated. The results show that a domain forward-switching process occurs during creep deformation while a domain backward-switching process takes place during recovery. In addition, it was found that the frequency of applied stress affects the saturation of the ferroelastic strain while its magnitude has an influence on the level of strain accumulated. Under static mechanical loading, it was found that the size of the crack-tip zone where stress-induced domain switching occurs with increase in the stress intensity factor but the degree of domain switching around the crack tip changes only slightly. Under cyclic electrical loading, the results present a strong link between the frequency of the applied field, remnant polarisation, domain switching and the resultant crack growth. The results show that polarisation fatigue, the size of the switching zone, and the crack growth rate is greater at lower loading frequency. The quantitative analysis of the time dependent mechanism as well as the effect of loading frequency and amplitude on domain switching was achieved by applying viscoelastic models. Importantly, these models can be used to explain domain switching behaviour and domain wall movement under cyclic loading and link these processes to macroscopic deformation.

Electrical loading.

Domain switching.

Ferroelectric ceramics.

An expansion of theoretical principles of Raman spectroscopy towards fully quantitative algorithms for the analysis of electronic materials and related devices / 電子材料および関連機器の解析アルゴリズムの定量化を目的としたラマン分光理論の拡張

Pezzotti, Giuseppe

23 January 2014

京都大学 / 0048 / 新制・論文博士 / 博士(理学) / 乙第12798号 / 論理博第1538号 / 新制||理||1566(附属図書館) / 80842 / (主査)教授 北川 宏, 教授 吉村 一良, 教授 竹腰 清乃理 / 学位規則第4条第2項該当 / Doctor of Science / Kyoto University / DGAM

Raman spectroscopy

piezoelectrics

semiconductors

domain switching

residual stress

400

圧電セラミックスにおける繰返し荷重および直流電界重畳下での疲労き裂進展挙動

白木原, 香織, SHIRAKIHARA, Kaori, 田中, 啓介, TANAKA, Keisuke, 秋庭, 義明, AKINIWA, Yoshiaki, 鈴木, 康悦, SUZUKI, Yasuyoshi, 向井, 寛克, MUKAI, Hirokatsu

06 1900

No description available.

Piezoelectric Ceramics

Lead Zirconate Titanate

Domain Switching

Fatigue Crack Propagation

Compliance Method

Electric Field

Fracto Graphy

Lattice Strain and Domain Switching Induced in Tetragonal PZT by Poling and Mechanical Loading

TANAKA, Keisuke, AKINIWA, Yoshiaki, SAKAIDA, Yoshihisa, KIMACHI, Hirohisa

10 1900

No description available.

Experimental Stress Analysis

Residual Stress

Ceramics

Bending

X-Ray Strain Measurement

Lead Zirconate Titanate

Polarization

Domain Switching

Lattice Strain

Microstrain

Crystal growth, guest ordering and ferroelastic properties of urea inclusion compounds

Rush, Jeremy Richard

January 1900

Doctor of Philosophy / Department of Chemistry / Mark D. Hollingsworth / The ferroelastic urea inclusion compound (UIC) of 2,10-undecanedione/urea exhibits a striking pseudoelastic memory effect. Although pseudoelasticity is possible for UICs containing only 2,10-undecanedione, introduction of a structurally similar guest impurity (2-undecanone) gives rise to rubber-like behavior, a form of pseudoelasticity. This phenomenon depends on both the crystal strain and the concentration of monoketone: above 13-14% 2-undecanone, pseudoelastic behavior is observed reliably, even at strains as high as 2.4%. The dramatic change in ferroelastic behavior over a small range of impurity content indicates that this is a critical threshold phenomenon. Because the impurity concentration has such a dramatic effect on domain switching, it was important to determine the sector-dependent patterns of incorporation of this relaxive impurity. Preliminary HPLC analyses of guest populations suggest that preferential incorporation of monoketone guests occurs between nonequivalent growth sectors, and that these patterns can be rationalized using a symmetry specific growth model. Birefringence mapping and HPLC studies of optically anomalous UICs containing mixtures of 2,9-decanedione and 2-decanone (which possess trigonal metric symmetry) suggest analogous patterns in guest incorporation and/or ordering that can also be rationalized. Although crystals of 2,9-decanedione/urea exhibit no ferroelastic strain at ambient temperature, they exhibit a proper ferroelastic phase transition near -170[degrees]C. It is proposed that differential perfection of domains gives rise to pseudoelasticity in UICs, and that relaxive impurities play an important role in the energetics of this process. Because ultrafast video studies of domain reversion kinetics demonstrate no clear correlation of observed rates with impurity content, it is proposed that the relaxive impurities facilitate spontaneous domain reversion by annealing stressed defect sites that would otherwise lead to irreversible or plastic domain switching. Following earlier work using synchrotron white beam X-ray topography, the driving force for domain reversion is thought to involve the presence of nanoscopic twins whose strain is epitaxially mismatched with neighboring daughter domains. The behavior of these nanoscopic twins was monitored with in-situ X-ray diffraction studies of stressed crystals, and this has led to a more thorough understanding of the role of these nanoscopic twins in the ferroelastic domain switching and rubber-like behavior in this class of materials.

ferroelastic domain switching

pseudoelastic memory effect

rubber-like behavior

guest impurity

preferential incorporation

symmetry specific growth model

Chemistry, Organic (0490)