Goktepeli, Gamze2025-04-132025-04-1320250961-95341873-2909https://doi.org/10.1016/j.biombioe.2025.107814Low surface area and the lack of hierarchical porous carbons (HPCs) structure limit the application areas of hydrochars. Therefore, in this study, self-activation of hydrochars by means of intrinsic inorganic elements was demonstrated as a novel approach for obtaining HPCs. Furthermore, the fate of intrinsic elements during the hydrothermal carbonization (HTC) process and the effects of intrinsic elements' quantity on chemical modification of hydrochars were evaluated. Hydrochars were produced at 220, 230, 240 degrees C; 23-, 24- and 25-h and 1/3, 1/4 and 1/5 (w/w) ratios. Hydrochars with highest and lowest intrinsic inorganic element quantities were decided with Taguchi experimental design to use in chemical (with ZnCl2, K2CO3 and H3BO3) and self-activation modification process conducted by heating hydrochars at 700 degrees C and 800 degrees C for 1 h. The worthy percentage of K in SSH passed to the process liquid, P completely remained in the hydrochars regardless of HTC condition. While the high inorganic element quantity in the unmodified hydrochars resulted in hydrochars with low surface area during the chemical modification, the opposite trend was observed for self-activation process. Surface area of unmodified hydrochars was increased from nearly 2 m(2)/g to the 400 m(2)/g with self-activation process. Additionally, all self-activated hydrochars had pore size lower than <2 nm in Density Functional Theory (DFT), which indicate the formation of micro and mesoporous structures addition to the macropores. Consequently, this study showed that inorganic elements have vital role for modification processes and HPCs can be successfully produced via intrinsic inorganic elements with shorter time and single stage.eninfo:eu-repo/semantics/closedAccessChemical ActivationHydrocharsIntrinsic Inorganic ElementsSelf-Activation ProcessSunflower Seed HuskArticle10.1016/j.biombioe.2025.1078142-s2.0-105000324449