Györgyi Glodán scite author profile

Györgyi Glodán

4Publications

57Citation Statements Received

134Citation Statements Given

How they've been cited

How they cite others

152

119

Affiliations

University of Manchester, University of Debrecen, University of Cumbria

Publications

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Production of hollow hemisphere shells by pure Kirkendall porosity formation in Au/Ag system

Glodán

Cserháti

Beszeda

et al. 2010

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Interdiffusion has been studied in Ag/Au hemispherical core-shell structures on sapphire substrate. In isothermal heat treatments first a relatively fast growth of nanovoids was observed, which was followed by a slower shrinkage process. The void formation is interpreted by pure Kirkendall-porosity formation since Ag-50%Au solid solution has been formed in the shell. In contrary, in all previous publications on hollow nanoshell formation a chemical reaction took place and the shell consisted of the reaction product ͑i.e., of sulphide or oxide͒. Furthermore, in these cases the shrinkage was observed at temperatures higher than the formation temperature. © 2010 American Institute of Physics. ͓doi:10.1063/1.3490675͔It is well-known that voids can be formed during interdiffusion in binary systems ͑Kirkendall porosity formation 1 or Frenkel effect 2,3 ͒. The origin of this effect is the resultant vacancy flow ͑caused by the inequality of the intrinsic atomic fluxes in the lattice frame of reference͒ oriented toward the faster component. In fact this resultant volume flow is responsible for the development of stress free strain in the diffusion zone: one side tends to shrink and the other one to expand. Additional stress free strains can also develop due to the difference of the atomic volumes and/or to the formation of intermetallic compounds in which the specific volumes of the constituents can be considerably different than in the parent phases. 4 The partial or full relaxation of these diffusional stresses can lead to the well-known Kirkendall shift: in case of vacancy mechanism, if the efficiency of the vacancy sources and sinks ͑at dislocations͒ is high enough, atomic planes will be removed/inserted at the corresponding fast/slow component of the diffusion couple. If this process is fast and complete then the stresses will be relaxed and the pure Darkenregime is realized. Thus the overall intermixing in the laboratory frame of reference is controlled by the larger diffusion coefficient. In real systems, however, more complex time evolution is expected. It can happen that the restricted efficiency of vacancy sinks leads to vacancy super saturation and porosity formation on the side of the faster component. These pores then can also sink vacancies and thus this will be a competing process with the vacancy annihilation at dislocations, i.e., with the Kirkendall shift. 2 Furthermore, the additional diffusional stresses can enhance or suppress the porosity formation. This complex interplay of the above effects is a delicate theoretical problem and it is expected that simple analytical solutions can work only at very special simple cases. In addition, if the sample geometry is closed ͑cylindrical, spherical samples͒, since the stress free strain fields are long range fields, the stress development and relaxation will certainly depend on the shape and size of the sample and for example a radius dependence of the processes are also expected. 4,5 In extreme circumstances even a switching between the Darken and Nernst-Pla...

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Temperature-dependent formation and shrinkage of hollow shells in hemispherical Ag/Pd nanoparticles

Glodán

Cserháti

Beke

2012

Philosophical Magazine

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It is shown that both the growth and shrinkage of hollow shells in Ag/Pd hemispherical core-shell nano structures took place at the same temperature. The crossover time, t cr , between these regimes is shifted to smaller values with increasing temperatures. This result confirms that the growth and the shrinkage regimes are controlled by the faster as well as the slower diffusion coefficients (D Ag as well as D Pd ), respectively. The pore radius, confirming recent theoretical predictions, linearly depends on the initial particle radius and the slope of this straight line increases with the average composition of the faster component.

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Thermal conductivity of spark plasma sintered SiC ceramics with Alumina and Yttria

Chai

Gao

Han

et al. 2021

Journal of the European Ceramic Society

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Discovery of a Low Thermal Conductivity Oxide Guided by Probe Structure Prediction and Machine Learning

et al. 2021

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We report the aperiodic titanate Ba 10 Y 6 Ti 4 O 27 with aroom-temperature thermal conductivity that equals the lowest reported for an oxide.T he structure is characterised by discontinuous occupancy modulation of each of the sites and can be considered as aq uasicrystal. The resulting localisation of lattice vibrations suppresses phonon transport of heat. This new lead material for low-thermal-conductivity oxides is metastable and located within aq uaternary phase field that has been previously explored. Its isolation thus requires ap recisely defined synthetic protocol. The necessary narrowing of the search space for experimental investigation was achieved by evaluation of titanate crystal chemistry,prediction of unexplored structural motifs that would favour synthetically accessible new compositions,and assessment of their properties with machine-learning models.

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