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An air‐stable, strongly reducing molecule benzyl viologen (BV) is used to induce charge‐transfer doping of the indium zinc oxide semiconductor in inkjet‐printed thin‐film transistors. The device mobility is improved from 5.8 ± 1.4 cm^2 V^−1 s^−1 in the undoped devices and reached up to 8.7 ± 1.0 cm^2 V^−1 s^−1 after BV treatment. Through measurement of frequency‐dependent admittance and capacitance, this work quantifies the density of interface states and shows that interfacial trap density is four times lower in the BV‐doped transistors compared to undoped devices. 

The well‐known coffee‐ring effect causes colloidal particles to convectively transport toward the contact line of an inkjet droplet leading to a nonuniform deposition of the colloidal particles. In this work, the self‐assembly of colloidal particles in a dual‐droplet inkjet printing configuration to produce a nearly monolayer closely packed deposition of colloidal particles that exhibits a colorful reflection are demonstrated. By controlling the ink surface tensions and jetting parameters, the wetting droplets (the second droplet) containing colloidal polystyrene (PS) nanoparticles quickly spread over the supporting droplets (the first droplet) upon impact. The well‐ordered deposition is achieved by tuning the solvent composition of the wetting droplets and functionalization of the PS nanoparticles to encourage a network formation among the colloidal particles at the air–droplet interface. The underlying self‐assembly mechanism is insensitive to substrates and can be applied to many other material/substrate combinations. Finally, the origin of the color generation is highlighted, and the potential of the dual‐droplet inkjet printing process is discussed for fabrication of optical devices.