Thin Glass Film between Ultrafine Conductor Particles in Thick‐Film Resistors

Chiang, Yet‐Ming; Silverman, L. A.; French, Roger H.; Cannon, R. M.

doi:10.1111/j.1151-2916.1994.tb05386.x

Cited by 140 publications

(93 citation statements)

References 18 publications

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“…If this problem were solved, engineers could confidently design interfaces with desired properties, e.g. increased toughness [2], tunable electrical conductivity [3] or enhanced sintering behaviour [4].…”

Section: Introductionmentioning

confidence: 99%

A genetic algorithm for predicting the structures of interfaces in multicomponent systems

et al. 2010

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Recent years have seen great advances in our ability to predict crystal structures from first principles. However, previous algorithms have focussed on the prediction of bulk crystal structures, where the global minimum is the target. Here, we present a general atomistic approach to simulate in multicomponent systems the structures and free energies of grain boundaries and heterophase interfaces with fixed stoichiometric and non-stoichiometric compositions. The approach combines a novel genetic algorithm using empirical interatomic potentials to explore the configurational phase space of boundaries, and thereafter refining structures and free energies with first principles electronic structure methods. We introduce a structural order parameter to bias the genetic algorithm search away from the global minimum (which would be bulk crystal), while not favouring any particular structure types, unless they lower the energy. We demonstrate the power and efficiency of the algorithm by considering nonstoichiometric grain boundaries in a ternary oxide, SrTiO 3 .

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Section: Introductionmentioning

confidence: 99%

A genetic algorithm for predicting the structures of interfaces in multicomponent systems

et al. 2010

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“…The generalization to a bimodal distribution, Eqs. (21,22), is straightforward. To calculate numerically the transport exponent t we use the transfer-matrix method of Derrida and Vannimenus applied to a simple cubic lattice of N − 1 sites in the z direction, N sites along y and L along the x direction.…”

Section: Monte Carlo Results On the Cubic Latticementioning

confidence: 99%

“…Micrographs reveal that the conducting grains are arranged in a network of filaments spanning the entire sample. 7,21,22 By taking into account the quasi-one dimensional structure of such filaments and by neglecting interactions with the insulating phase, we show that the resulting P (r) can decay much slower than the tunneling decay leading to nonuniversal behavior of transport. This paper is organized as follows.…”

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confidence: 97%

Segregated tunneling-percolation model for transport nonuniversality

et al. 2003

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We propose a theory of the origin of transport nonuniversality in disordered insulating-conducting compounds based on the interplay between microstructure and tunneling processes between metallic grains dispersed in the insulating host. We show that if the metallic phase is arranged in quasi-one dimensional chains of conducting grains, then the distribution function of the chain conductivities g has a power-law divergence for g → 0 leading to nonuniversal values of the transport critical exponent t. We evaluate the critical exponent t by Monte Carlo calculations on a cubic lattice and show that our model can describe universal as well nonuniversal behavior of transport depending on the value of few microstructural parameters. Such segregated tunneling-percolation model can describe the microstructure of a quite vast class of materials known as thick-film resistors which display universal or nonuniversal values of t depending on the composition.

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“…The final conductive lines are composed of flocced silver particles and glass matrix. 29,30 The geometry, morphology, and components of the conductive lines have been studied to minimize shading of the cells while maintaining good conductance. [31][32][33] Research on the conductive lines has typically focused on the conductor line microstructure throughout the firing process 34 and the interface between the screen-printed conductive lines and the emitter as a function of precursor constituents to optimize the initial electrical performance.…”

Section: Mesoscale Description Of Solar Cell Interfaces and Contactsmentioning

confidence: 99%

Insights into metastability of photovoltaic materials at the mesoscale through massiveI–Vanalytics

Peshek

Fada

et al. 2016

Journal of Vacuum Science &Amp; Technology B, Nanotechnology and Microelectronics: Materials, Processing, Measurement, and Phen

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The authors demonstrate the feasibility of quantifying cell-level performance heterogeneity from module-level I–V curves by determining conditions of bypass diode turn-on. Analysis of these curves falls outside of typical diode-based models of photovoltaic (PV) performance. The authors show that this approach can leverage statistical and machine learning techniques for broad application to massive datasets, and combine those insights with simulations and laboratory-based experiments to provide useful information into the metastability of the interfaces of a PV cell. The authors find good agreement between the experimentally determined curves and the simulated curves, which guide the variable selection in the massive dataset collected from sites in Cleveland, OH, USA, the Negev Desert, Israel, Isla Gran Canaria, Spain, and Mount Zugspitze, Germany.

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Thin Glass Film between Ultrafine Conductor Particles in Thick‐Film Resistors

Cited by 140 publications

References 18 publications

A genetic algorithm for predicting the structures of interfaces in multicomponent systems

A genetic algorithm for predicting the structures of interfaces in multicomponent systems

Segregated tunneling-percolation model for transport nonuniversality

Insights into metastability of photovoltaic materials at the mesoscale through massiveI–Vanalytics

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