Gökçen Akgül, A. Et Al. 2023. Electrochemical Energy Storage Capacity of Surface Engineered Renewable Carbon Derived from Industrial Tea Waste by HNO3 and K2CO3. Surface Engineering and Applied Electrochemistry , vol.59, no.2 , 199-209.

Gökçen Akgül, A., OSKAY, K. O., Buldu-Akturk, M., Karamustafa, A., Sözer, S., Maden, T. B., ... Erdem, E.(2023). Electrochemical Energy Storage Capacity of Surface Engineered Renewable Carbon Derived from Industrial Tea Waste by HNO3 and K2CO3. Surface Engineering and Applied Electrochemistry , vol.59, no.2, 199-209.

Gökçen Akgül, Akgul Et Al. "Electrochemical Energy Storage Capacity of Surface Engineered Renewable Carbon Derived from Industrial Tea Waste by HNO3 and K2CO3," Surface Engineering and Applied Electrochemistry , vol.59, no.2, 199-209, 2023

Gökçen Akgül, Akgul G. Et Al. "Electrochemical Energy Storage Capacity of Surface Engineered Renewable Carbon Derived from Industrial Tea Waste by HNO3 and K2CO3." Surface Engineering and Applied Electrochemistry , vol.59, no.2, pp.199-209, 2023

Gökçen Akgül, A. Et Al. (2023) . "Electrochemical Energy Storage Capacity of Surface Engineered Renewable Carbon Derived from Industrial Tea Waste by HNO3 and K2CO3." Surface Engineering and Applied Electrochemistry , vol.59, no.2, pp.199-209.

@article{article, author={Akgul Gökçen Akgül Et Al. }, title={Electrochemical Energy Storage Capacity of Surface Engineered Renewable Carbon Derived from Industrial Tea Waste by HNO3 and K2CO3}, journal={Surface Engineering and Applied Electrochemistry}, year=2023, pages={199-209} }