Electrode Defects in Multilayer Capacitors Part II: Finite Element Analysis of Local Field Enhancement and Leakage Current in Three‐Dimensional Microstructures

Samantaray, Malay M.; Gurav, Abhijit; Dickey, Elizabeth C.; Randall, Clive A.

doi:10.1111/j.1551-2916.2011.04768.x

Cited by 29 publications

(15 citation statements)

References 28 publications

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“…34 As observed in the VC-SEM images, local perturbations in electric potential take place due the presence of these electrode defects, as predicted by the finite element modeling.…”

Section: Discussionmentioning

confidence: 55%

Electrode Defects in Multilayer Capacitors Part I: Modeling the Effect of Electrode Roughness and Porosity on Electric Field Enhancement and Leakage Current

Samantaray

Gurav²,

Dickey

et al. 2011

J. Am. Ceram. Soc.

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Multilayer capacitors consist of multiple, often hundreds of capacitors connected in parallel to maximize volumetric efficiency. As the dielectric and electrode layer thicknesses are scaled down, microstructural imperfections become increasingly influential on the device electrical performance. Specifically, the presence of nonplanar and discontinuous electrodes can lead to local field enhancements while the relative morphologies of two adjacent electrodes determine variations in the local dielectric thickness. To study the effects of electrode morphologies, an analytical approach is taken to calculate the field enhancement and leakage current with respect to an ideal parallel‐plate capacitor. It is shown that the electrode roughness causes the leakage current to increase with respect to that of the ideal flat parallel‐plate capacitor. To further include the effects of local curvature on electric field enhancements, finite element methods are used to calculate field distributions within capacitor structures containing rough interfaces and porosity. In these simulations, the effects of electrode pore diameters, dielectric layer thickness, and the amplitude and wavelength of the electrode roughness are studied.

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“…34 As observed in the VC-SEM images, local perturbations in electric potential take place due the presence of these electrode defects, as predicted by the finite element modeling.…”

Section: Discussionmentioning

confidence: 55%

Electrode Defects in Multilayer Capacitors Part I: Modeling the Effect of Electrode Roughness and Porosity on Electric Field Enhancement and Leakage Current

Samantaray

Gurav²,

Dickey

et al. 2011

J. Am. Ceram. Soc.

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“…Thus, the high‐local electric field places severe limitations on device performance due to enhanced local leakage current, and therefore reduces the operating voltage of the devices. As discussed in a prior study, the effect of electrode defects are magnified as one approaches submicrometer dielectric layers, and therefore compromises the advancement toward higher volumetric capacitance through miniaturization . Under such conditions, it becomes extremely important to have smoother and more continuous electrodes in state‐of‐the art MLCCs.…”

Section: Resultsmentioning

confidence: 99%

“…These volumes are then used as a model to simulate electric field distribution in the dielectric layer by finite‐element modeling in and around the electrode region using the finite‐element solver COMSOL. The complete details of the 3‐D visualization and simulation technique are discussed elsewhere . .…”

Section: Methodsmentioning

confidence: 99%

“…demonstrated the dependence of leakage current on the metal–insulator interface morphology due to local electric field enhancements around roughness . In the past, some of these observations have been quantified by calculating the electric field distribution in the presence of electrode defects such as porosities and roughness . Both analytical and numerical approaches have revealed defects such as the sites of high‐local electric fields, which in turn gave rise to higher leakage currents.…”

Section: Introductionmentioning

confidence: 99%

“…7,14 In the past, some of these observations have been quantified by calculating the electric field distribution in the presence of electrode defects such as porosities and roughness. 15,16 Both analytical and numerical approaches have revealed defects such as the sites of high-local electric fields, which in turn gave rise to higher leakage currents. Levi et al demonstrated that even the presence of grain-boundary grooving in a Ni electrode could lead to an enhanced electric field, and thus, could reduce the interface resistance in those regions.…”

Section: Introductionmentioning

confidence: 99%

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Effect of Firing Rates on Electrode Morphology and Electrical Properties of Multilayer Ceramic Capacitors

et al. 2011

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Over the past decade, multilayer ceramic capacitors (MLCCs) have been able to achieve very high volumetric capacitance due to continuous improvement in their process technology. However, the performance of these devices is severely limited by the presence of electrode defects such as electrode porosity and roughness. To assess the effect of microstructure on MLCC performance, two sets of multilayer capacitors subjected to different processing conditions are compared for their microstructure and electrical properties. It is shown that more continuous and planar electrode morphology leads to lower local electric fields and thus, superior performance. These computational predictions are verified using electrical property measurements. Capacitors with higher electrode continuity exhibit proportionally higher capacitance, provided the grain‐size distributions are similar. From the leakage current measurements, it is found that the Schottky barrier at the electrode–dielectric interface controls the conduction mechanism. This barrier height is adversely affected by the microstructural defects such as electrode discontinuities and roughness. These results are further supported by frequency‐dependent impedance measurements.

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Studies on Ni termination of a multilayer ceramic capacitor with high capacitance by using DC electrodeposition

Lee,

Puteri,

Lee

et al. 2023

J Electroceram

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Electrode Defects in Multilayer Capacitors Part II: Finite Element Analysis of Local Field Enhancement and Leakage Current in Three‐Dimensional Microstructures

Cited by 29 publications

References 28 publications

Electrode Defects in Multilayer Capacitors Part I: Modeling the Effect of Electrode Roughness and Porosity on Electric Field Enhancement and Leakage Current

Electrode Defects in Multilayer Capacitors Part I: Modeling the Effect of Electrode Roughness and Porosity on Electric Field Enhancement and Leakage Current

Effect of Firing Rates on Electrode Morphology and Electrical Properties of Multilayer Ceramic Capacitors

Studies on Ni termination of a multilayer ceramic capacitor with high capacitance by using DC electrodeposition

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