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A Green High-k Dielectric from Modified Carboxymethyl Cellulose-Based with Dextrin.

Leon Lukhas SantosoSuhendro Purbo PrakosoHai-Khue BuiQi-An HongSsu-Yu HuangTai-Chin ChiangKuan-Yeh HuangSiti NurkhamidahDewi TristantiniYu-Cheng Chiu
Published in: Macromolecular rapid communications (2024)
Many crucial components inside electronic devices are made from non-renewable, non-biodegradable, and potentially toxic materials, leading to environmental damage. Finding alternative green dielectric materials is mandatory to align with global sustainable goals. Carboxymethyl cellulose (CMC) is a bio-polymer derived from cellulose and has outstanding properties. Herein, citric acid, dextrin, and CMC based hydrogels are prepared, which are biocompatible and biodegradable and exhibit rubber-like mechanical properties, with Young modulus values of 0.89 MPa. Hence, thin film CMC-based hydrogel is explored as a suitable green high-k dielectric candidate for operation at low voltages, demonstrating a high dielectric constant of up to 78. These fabricated transistors reveal stable high capacitance (2090 nF cm -2 ) for ≈±3 V operation. Using a polyelectrolyte-type approach and poly-(2-vinyl anthracene) (PVAn) surface modification, this study demonstrates a thin dielectric layer (d ≈30 nm) with a small voltage threshold (V th ≈-0.8 V), moderate transconductance (g m ≈65 nS), and high ON-OFF ratio (≈10 5 ). Furthermore, the dielectric layer exhibits stable performance under bias stress of ± 3.5 V and 100 cycles of switching tests. The modified CMC-based hydrogel demonstrates desirable performance as a green dielectric for low-voltage operation, further highlighting its biocompatibility.
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