Tip-Induced Etching and Vacancy Island Evolution on 2H-TaS<sub>2</sub> Revealed by STM

Tip-Induced Etching and Vacancy Island Evolution on 2H-TaS<sub>2</sub> Revealed by STM

Recent research on 2D materials using scanning probe microscopy reveals that the surface of transition metal dichalcogenides can be etched during the measurement via either a tunneling-field-driven or a scanning probe-driven process. The tip-induced manipulation of the surface structure and defects...

Descrizione completa

Salvato in:
Dettagli Bibliografici
Autore principale: Dejia Kong (4269937) (author)
Altri autori: Richard Peckham (22395851) (author), Kory Burns (22395854) (author), Zhiqiang Mao (1328169) (author), Seng Huat Lee (1902982) (author), Jordan A. Hachtel (4400677) (author), Zheng Gai (1668583) (author), Ian Harrison (1643863) (author), Petra Reinke (373886) (author)
Pubblicazione: 2025
Soggetti:
Medicine
Microbiology
Cell Biology
Evolutionary Biology
Ecology
Science Policy
Infectious Diseases
Space Science
Environmental Sciences not elsewhere classified
Biological Sciences not elsewhere classified
Physical Sciences not elsewhere classified
transition metal dichalcogenides
stm recent research
quantified using ai
measurement via either
chemical vapor transport
growth rate variance
vacancy island evolution
newly exposed layers
surface defect inventory
linear growth rate
2 </ sub
mobile surface islands
induced etching mechanism
vacancy islands
growth kinetics
includes linear
entire layers
surface structure
isolated islands
induced manipulation
induced etching
induced chemistry
individual islands
work paves
water adsorbates
top layer
sequential removal
scanning probe
quantitative analysis
imaging trigger
extended periods
etching kinetics
Tags: Aggiungi Tag
Nessun Tag, puoi essere il primo ad aggiungerne!!
Descrizione
Riassunto:Recent research on 2D materials using scanning probe microscopy reveals that the surface of transition metal dichalcogenides can be etched during the measurement via either a tunneling-field-driven or a scanning probe-driven process. The tip-induced manipulation of the surface structure and defects is a first step toward nanolithography using scanning probes. Real-space scanning tunneling microscopy experiments provide a surface defect inventory, which includes linear and point defects for 2H-TaS<sub>2</sub> grown by chemical vapor transport. Extended periods of imaging trigger the formation of vacancy islands that grow and coalesce over time, leading to the sequential removal of entire layers. The growth kinetics of vacancies were observed over extended periods and quantified using AI and conventional image analysis tools. The vacancy islands have a linear growth rate of their perimeter and corresponding parabolic growth rates in the area for isolated islands. The growth rate variance of individual islands is discussed in the framework of etching mechanisms including tip-induced chemistry, etching by water adsorbates, and native defects that support vacancy island nucleation in the TaS<sub>2</sub> surface. New vacancy islands emerge rapidly in newly exposed layers after the top layer is removed. Small and mobile surface islands that are redeposited are revealed to participate in the tip-induced etching mechanism. The quantitative analysis of etching kinetics is a first step toward automated nanostructuring of TaS<sub>2</sub> surfaces. This work paves the way to use scanning tunneling microscopy to build more complex 2D material structures.

Documenti analoghi