Small bandgap in atomically precise 17-atom-wide armchair-edged graphene nanoribbons

Abstract: Bottom-up synthesis of graphene nanoribbons (GNRs) may open new possibilities in future electronic devices owing to their tunable electronic structure, which depends strongly on their well-defined width and edge geometry. For instance, armchair-edged GNRs (AGNRs) exhibit width-dependent bandgaps. However, the bandgaps of AGNRs synthesized experimentally so far are relatively large, well above 1 eV. Such a large bandgap may deteriorate device performance due to large Schottky barriers and carrier effective mass… Show more

“…It has a small band gap of 0.19 eV on Au(111) and with FT-STS an effective mass m CB = m VB = 0.06 m e was found. 56 From the experimental characterization of AGNRs, the three predicted D families become apparent in accordance with theory. When selecting AGNRs for devices, a tradeoff has to be made between band gap and effective mass, where wider band gaps lead to larger effective carrier masses and therefore, lower electron mobility.…”

“…Using such a design strategy, atomically precise 9-, 13-and 17-AGNRs have been successfully synthesized. 56,57 In addition, steric hindrance has also been identified as a useful concept for the synthesis of cGNRs and chGNRs.…”

“…198 Recently, the 13-AGNR was also synthesized from 16 by Yamaguchi et al on Au (111). 56 This leads to a ribbon with identical interior, but notably with a different edge orientation at the termini. They reported a similar band gap of 1.34 eV.…”

“…It has a small band gap of 0.19 eV on Au(111) and with FT-STS an effective mass m CB = m VB = 0.06 m e was found. 56 …”

Atomically precise graphene nanoribbons: interplay of structural and electronic properties

“…It has a small band gap of 0.19 eV on Au(111) and with FT-STS an effective mass m CB = m VB = 0.06 m e was found. 56 From the experimental characterization of AGNRs, the three predicted D families become apparent in accordance with theory. When selecting AGNRs for devices, a tradeoff has to be made between band gap and effective mass, where wider band gaps lead to larger effective carrier masses and therefore, lower electron mobility.…”

“…Using such a design strategy, atomically precise 9-, 13-and 17-AGNRs have been successfully synthesized. 56,57 In addition, steric hindrance has also been identified as a useful concept for the synthesis of cGNRs and chGNRs.…”

“…198 Recently, the 13-AGNR was also synthesized from 16 by Yamaguchi et al on Au (111). 56 This leads to a ribbon with identical interior, but notably with a different edge orientation at the termini. They reported a similar band gap of 1.34 eV.…”

“…It has a small band gap of 0.19 eV on Au(111) and with FT-STS an effective mass m CB = m VB = 0.06 m e was found. 56 …”

Atomically precise graphene nanoribbons: interplay of structural and electronic properties

“…To this end, on-surface synthesis based on the polymerization and planarization of tailor-made molecular precursors on metal surfaces under ultrahigh vacuum (UHV) conditions appears particularly powerful and offers the additional advantage of in-situ monitoring by atomic-resolution scanning probe microscopy [5][6][7][8][9][10]. Since the initial demonstration of 7-atomwide armchair-type GNRs (7-AGNRs) on a Au(111) surface using 10,10'-dibromo-9,9'-bianthryl (DBBA) as a precursor [11], a range of GNRs with different structures have been prepared via on-surface synthesis, such as armchair GNRs (N-AGNRs) with different widths N (N = 5, 6, 8, 9, 10, 13, 15 and 17) [12][13][14][15][16][17][18][19], zigzag GNRs (ZGNRs) [20], chevron-type GNRs [11,21], chiral (3,1)-GNRs containing zigzag and armchair edges [22], and heteroatom-doped GNRs with boron, nitrogen, oxygen, or sulfur [23][24][25][26][27][28][29][30]. π-Extension of 7-AGNRs through aryl-substitution of DBBA turned out to be of special value.…”

On-surface activation of benzylic C-H bonds for the synthesis of pentagon-fused graphene nanoribbons

Introduction to Atomically Precise Nanochemistry