| Pyrolysis kinetics of hazelnut husk using thermogravimetric analysis S Ceylan, Y Topçu Bioresource technology 156, 182-188, 2014 | 414 | 2014 |
| Pyrolysis of high ash sewage sludge: Kinetics and thermodynamic analysis using Coats-Redfern method SR Naqvi, R Tariq, Z Hameed, I Ali, M Naqvi, WH Chen, S Ceylan, ... Renewable energy 131, 854-860, 2019 | 357 | 2019 |
| Thermokinetic and TG/DSC-FTIR study of pea waste biomass pyrolysis E Müsellim, MH Tahir, MS Ahmad, S Ceylan Applied Thermal Engineering 137, 54-61, 2018 | 309 | 2018 |
| Improved prediction of higher heating value of biomass using an artificial neural network model based on proximate analysis H Uzun, Z Yıldız, JL Goldfarb, S Ceylan Bioresource Technology 234, 122-130, 2017 | 165 | 2017 |
| Pyrolysis kinetics and thermal characteristics of microalgae Nannochloropsis oculata and Tetraselmis sp. S Ceylan, D Kazan Bioresource technology 187, 1-5, 2015 | 148 | 2015 |
| Thermal behaviour and kinetics of alga Polysiphonia elongata biomass during pyrolysis S Ceylan, Y Topcu, Z Ceylan Bioresource Technology 171, 193-198, 2014 | 123 | 2014 |
| Demonstrating the suitability of canola residue biomass to biofuel conversion via pyrolysis through reaction kinetics, thermodynamics and evolved gas analyses MH Tahir, G Çakman, JL Goldfarb, Y Topcu, SR Naqvi, S Ceylan Bioresource technology 279, 67-73, 2019 | 119 | 2019 |
| Pyrolysis reaction models of waste tires: Application of Master-Plots method for energy conversion via devolatilization DI Aslan, P Parthasarathy, JL Goldfarb, S Ceylan Waste Management 68, 405-411, 2017 | 116 | 2017 |
| Green tide to green fuels: TG–FTIR analysis and kinetic study of Ulva prolifera pyrolysis S Ceylan, JL Goldfarb Energy Conversion and Management 101, 263-270, 2015 | 113 | 2015 |
| Application of artificial neural networks to co-combustion of hazelnut husk–lignite coal blends Z Yıldız, H Uzun, S Ceylan, Y Topcu Bioresource technology 200, 42-47, 2016 | 105 | 2016 |
| Estimation of biomass higher heating value (HHV) based on the proximate analysis: Smart modeling and correlation A Dashti, AS Noushabadi, M Raji, A Razmi, S Ceylan, AH Mohammadi Fuel 257, 115931, 2019 | 96 | 2019 |
| Thermokinetic analysis and product characterization of Medium Density Fiberboard pyrolysis DI Aslan, B Özoğul, S Ceylan, F Geyikçi Bioresource technology 258, 105-110, 2018 | 75 | 2018 |
| Product quality optimization in an integrated biorefinery: conversion of pistachio nutshell biomass to biofuels and activated biochars via pyrolysis S Işıtan, S Ceylan, Y Topcu, C Hintz, J Tefft, T Chellappa, J Guo, ... Energy Conversion and Management 127, 576-588, 2016 | 68 | 2016 |
| Investigation of pyrolysis kinetics and thermal behavior of Invasive Reed Canary (Phalaris arundinacea) for bioenergy potential H Alhumade, JCG da Silva, MS Ahmad, G Çakman, A Yıldız, S Ceylan, ... Journal of Analytical and Applied Pyrolysis 140, 385-392, 2019 | 67 | 2019 |
| Impact of Co-Hydrothermal carbonization of animal and agricultural waste on hydrochars’ soil amendment and solid fuel properties D Mariuzza, JC Lin, M Volpe, L Fiori, S Ceylan, JL Goldfarb Biomass and Bioenergy 157, 106329, 2022 | 60 | 2022 |
| Renewable fuels from pyrolysis of Dunaliella tertiolecta: an alternative approach to biochemical conversions of microalgae N Söyler, JL Goldfarb, S Ceylan, MT Saçan Energy 120, 907-914, 2017 | 58 | 2017 |
| Second-generation sustainability: application of the distributed activation energy model to the pyrolysis of locally sourced biomass–coal blends for use in co-firing scenarios JL Goldfarb, S Ceylan Fuel 160, 297-308, 2015 | 53 | 2015 |
| Integrated thermochemical conversion process for valorizing mixed agricultural and dairy waste to nutrient-enriched biochars and biofuels JC Lin, D Mariuzza, M Volpe, L Fiori, S Ceylan, JL Goldfarb Bioresource Technology 328, 124765, 2021 | 52 | 2021 |
| Fast pyrolysis of date palm biomass using Py-GCMS G Bensidhom, M Arabiourrutia, ABH Trabelsi, M Cortazar, S Ceylan, ... Journal of the Energy Institute 99, 229-239, 2021 | 49 | 2021 |
| Sustainable hydrocarbon fuels via “one-pot” catalytic deoxygenation of waste cooking oil using inexpensive, unsupported metal oxide catalysts A Yıldız, JL Goldfarb, S Ceylan Fuel 263, 116750, 2020 | 49 | 2020 |
