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Functionalized MXene ink enables environmentally stable printed electronics

Tae Yun Ko, Heqing Ye, G. Murali, Seul‐Yi Lee, Young Ho Park, Jihoon Lee, Juyun Lee, Dong‐Jin Yun, Yury Gogotsi, Seon Joon Kim, Se Hyun Kim, Yong Jin Jeong, Soo‐Jin Park, Insik In

2024Nature Communications67 citationsDOIOpen Access PDF

Abstract

Abstract Establishing dependable, cost-effective electrical connections is vital for enhancing device performance and shrinking electronic circuits. MXenes, combining excellent electrical conductivity, high breakdown voltage, solution processability, and two-dimensional morphology, are promising candidates for contacts in microelectronics. However, their hydrophilic surfaces, which enable spontaneous environmental degradation and poor dispersion stability in organic solvents, have restricted certain electronic applications. Herein, electrohydrodynamic printing technique is used to fabricate fully solution-processed thin-film transistors with alkylated 3,4-dihydroxy-L-phenylalanine functionalized Ti 3 C 2 T x (AD-MXene) as source, drain, and gate electrodes. The AD-MXene has excellent dispersion stability in ethanol, which is required for electrohydrodynamic printing, and maintains high electrical conductivity. It outperformed conventional vacuum-deposited Au and Al electrodes, providing thin-film transistors with good environmental stability due to its hydrophobicity. Further, thin-film transistors are integrated into logic gates and one-transistor-one-memory cells. This work, unveiling the ligand-functionalized MXenes’ potential in printed electrical contacts, promotes environmentally robust MXene-based electronics (MXetronics).

Topics & Concepts

Materials scienceMXenesTransistorMicroelectronicsElectronicsFlexible electronicsNanotechnologyOrganic electronicsOptoelectronicsElectrodePrinted electronicsElectrohydrodynamicsThin-film transistorInkwellElectrical engineeringLayer (electronics)VoltageComposite materialChemistryPhysical chemistryEngineeringMXene and MAX Phase MaterialsAdvanced Sensor and Energy Harvesting MaterialsAdvanced Memory and Neural Computing