Molecular-Vapor-Assisted Low-Temperature Growth of Graphene Nanoribbons

Abstract: Conventional on-surface synthesis under ultrahigh vacuum deposition has been used to synthesize various types of graphene nanoribbons (GNRs). The dehydrogenation reaction from a prepolymer to GNR requires catalysis with a metal substrate at high temperatures, which suffers from undesired side reactions that decompose introduced functional substituents during conversion to GNRs. To overcome these drawbacks, we have developed a new method, molecular-vapor-assisted low-temperature growth (MVLTG), based on a massi… Show more

“…To solve this problem, we developed a new technique called "molecular-vapor-assisted low-temperature growth (MVLTG)", which enables conversion from prepolymer to GNR without decomposition of thermally fragile functional substituents, [53][54][55] such as butoxy groups, through exposure to a gaseous hydrogen acceptor (Figure 9a). [56] This method is based on exposing prepolymers grown by two-zone CVD to a controlled amount of oxygen gas or vaporized DDQ at a given temperature, which can be called a "gas-phase Scholl reaction." Isotactic prepolymers of [3, are converted into polar GNRs via an MVLTG technique capable of promoting dehydrogenation reactions by exposure to oxygen (Figure 9b-e).…”

On‐Surface Fabrication toward Polar 2D Macromolecular Crystals

“…To solve this problem, we developed a new technique called "molecular-vapor-assisted low-temperature growth (MVLTG)", which enables conversion from prepolymer to GNR without decomposition of thermally fragile functional substituents, [53][54][55] such as butoxy groups, through exposure to a gaseous hydrogen acceptor (Figure 9a). [56] This method is based on exposing prepolymers grown by two-zone CVD to a controlled amount of oxygen gas or vaporized DDQ at a given temperature, which can be called a "gas-phase Scholl reaction." Isotactic prepolymers of [3, are converted into polar GNRs via an MVLTG technique capable of promoting dehydrogenation reactions by exposure to oxygen (Figure 9b-e).…”

On‐Surface Fabrication toward Polar 2D Macromolecular Crystals