“…On-surface synthesis of low-dimensional nanostructures has been extensively studied because it has many advantages as a result of the surface confinement effect compared to the traditional solution method. − The bottom-up assembled strategy guarantees the precision of on-surface synthesis, which involves multiple reaction types, for instance, Ullmann coupling, − Glaser coupling, − Sonogashira coupling, , cross coupling, − cyclodehydrogenation, etc. − On the other hand, graphene nanoribbons (GNRs) have received tremendous attention from researchers among many graphene materials, because they exhibit a wide range of tunable bandgaps that facilitate the applications in molecular electronics and related single-molecule devices, − like organic field-effect transistors, − reversible photoswitching, tunable electroluminescence, etc. − In particular, GNRs with various widths, edge structures, and even different cavities have been fabricated through Ullmann coupling and further cyclodehydrogenation based on rational design and utilization of a single precursor. − There exist many factors affecting the above-mentioned reaction processes and final products, such as the template effect of substrates, , active sites and symmetry of the precursors, ,, thermodynamics, and kinetics . However, the controlled synthesis of GNR derivatives by multiple precursors with different symmetries has been scarcely investigated, which may bring great diversity to the final products.…”