Area selective deposition using alternate deposition and etch super-cycle strategies.

Area selective deposition (ASD) is a bottom-up process leading to a uniform deposition in only desired areas of a patterned substrate, avoiding the use of photolithography for patterning. However, whatever the strategy used to develop selective deposition by atomic layer deposition, there always comes a time when selectivity becomes defective and growth in undesired substrate areas must be corrected. This leads to the design of ASD by super-cycle alternating deposition and etch. Recent examples from the literature show a great diversity in the design of the etching step and indicate that the optimization of selective deposition by super-cycles is only possible through a careful optimization of the etching step parameters (chemistry, frequency, duration, etc.). In this paper, we discuss how to optimize this step and we show that different approaches can be developed to optimize the overall ASD process throughput, while simultaneously limiting process drift and contamination. We also show that complementary selective properties can prove a valuable leverage enabling ASD processes based on super-cycles, such as structure selective deposition, whereby a difference in thin film morphology in growth and non-growth areas can be smartly taken advantage of during the etching step.

DNA Origami for Silicon Patterning.

Desoxyribonucleic acid (DNA) origami architectures are a promising tool for ultimate lithography because of their ability to generate nanostructures with a minimum feature size down to 2 nm. In this paper, we developed a method for silicon (Si) nanopatterning to face up current limitations for high-resolution patterning with standard microelectronic processes. For the first time, a 2 nm-thick 2D DNA origami mask, with specific design composed of three different square holes (with a size of 10 and 20 nm), is used for positive pattern transfer into a Si substrate using a 15 nm-thick silicon dioxide (SiO2) layer as an intermediate hard mask. First, the origami mask is transferred onto the SiO2 underlayer, by an HF vapor-etching process. Then, the Si underlayer is etched using an HBr/O2 plasma. Each hole is transferred in the SiO2 layer and the 20 nm-sized holes are transferred into the final stack (Si). The resulting patterns exhibited a lateral resolution in the range of 20 nm and a depth of 40 nm. Patterns are fully characterized by atomic force microscopy, scanning electron microscopy, focused ion beam-transmission electron microscopy, and ellipsometry measurements.