Surface polarization, field homogeneity, and dielectric breakdown in ordered and disordered nanodielectrics based on gold–polystyrene superlattices
- Hybrid dielectrics were prepared from dispersions of nanoparticles with gold cores (diameters from 2.9 nm to 8.2 nm) and covalently bound thiol-terminated polystyrene shells (5000 Da and 11 000 Da) in toluene. Their microstructure was investigated with small angle X-ray scattering and transmission electron microscopy. The particles arranged in nanodielectric layers with either face-centered cubic or random packing, depending on the ligand length and core diameter. Thin film capacitors were prepared by spin-coating inks on silicon substrates, contacted with sputtered aluminum electrodes, and characterized with impedance spectroscopy between 1 Hz and 1 MHz. The dielectric constants were dominated by polarization at the gold–polystyrene interfaces that we could precisely tune via the core diameter. There was no difference in the dielectric constant between random and supercrystalline particle packings, but the dielectric losses depended on the layer structure. A model that combines Maxwell–Wagner–Sillars theory and percolation theory described the relationship of the specific interfacial area and the dielectric constant quantitatively. The electric breakdown of the nanodielectric layers sensitively depended on particle packing. A highest breakdown field strength of 158.7 MV m−1 was found for the sample with 8.2 nm cores and short ligands that had a face-centered cubic structure. Breakdown apparently is initiated at the microscopic maxima of the electric field that depends on particle packing. The relevance of the results for industrially produced devices was demonstrated on inkjet printed thin film capacitors with an area of 0.79 mm2 on aluminum coated PET foils that retained their capacity of 1.24 ± 0.01 nF@10 kHz during 3000 bending cycles.
Document Type: | Article |
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Author: | Roman BuchheitORCiD, Bart-Jan NiebuurORCiD, Lola González-GarcíaORCiD, Tobias KrausORCiD |
URN: | urn:nbn:de:bsz:291:415-5807 |
DOI: | https://doi.org/10.1039/D3NR01038D |
Parent Title (English): | Nanoscale |
Volume: | 15 |
First Page: | 7526 |
Last Page: | 7536 |
Language: | English |
Year of first Publication: | 2023 |
Release Date: | 2023/05/09 |
Impact: | 08.307 (2021) |
Scientific Units: | Structure Formation |
Electrofluids | |
DDC classes: | 500 Naturwissenschaften und Mathematik / 540 Chemie |
Open Access: | Open Access |
Signature: | INM 2023/060 |
Licence (German): | Creative Commons - CC BY - Namensnennung 4.0 International |