In this work, we demonstrated that the co-crystallization strategy has offered an efficient and promising alternative route to achieve high-performance n-type semiconductors through charge-transport switching from pristine p-type systems. By using a simple "green synthesis" process through molecular "doping" with F(4)TCNQ into a p-type planar azaacene derivative TMIQ (0.27 cm(2) V-1 s(-1)) host, charge transport characteristic switching occurs with a high electron mobility of 0.12 cm(2) V-1 s(-1) under atmospheric conditions obtained for the D-A complex TMF4TQ (cocrystal). The reasons for such switching lie in the ingenious energy level and molecular packing arrangement tailoring. Specifically, the insertion of F(4)TCNQ molecules has led to packing transformation from herringbone stacking (TMIQ) to a dense 2D brick arrangement and the low-lying LUMO levels (-4.55 eV) aligned to gold electrodes, thereby facilitating efficient electron injection and transport, and ensuring the air-stable nature, which is further confirmed using theoretical calculations. We believe that our work would provide new insights into high-performance air-stable n-type organic semiconductors exploration.

• Institution
  北京大学; 北京化工大学; 南阳理工学院