Herein, a self-supported carbon network is designed through the sole pyrolysis of Carica papaya seeds (biomass) without any activation agent and demonstrates their field emission and supercapacitor applications. The pyrolysis of seeds in the argon atmosphere leads to the formation of interconnected, rod-like structures. Furthermore, the hydrofluoric acid treatment not only removed the impurities but also resulted in the formation of CaF2 nanocrystals with the addition of F-doping. From the field emission studies, the turn-on field values defined at an emission current density of ~ 10 µA/cm2 were found to be ~2.16 and 1.21 V/µm for as-prepared carbon and F-doped carbon, respectively. Notably, F-doped carbon exhibits a high emission current density of ~9.49 mA/cm2 and has been drawn at an electric field of ~2.29 V/µm. The supercapacitor studies were carried out to demonstrate the multi-functionality of the prepared materials. The F-doped carbon electrode material exhibits the highest specific capacitance of 234 F g−1 at 0.5 A g−1. To demonstrate the actual supercapacitor application, the HFC // HFC symmetric coin cell supercapacitor device was assembled. The overall multifunctional applicability of the fabricated hybrid structures provides a futuristic approach to field emission and energy storage applications.