Thermal & chemical analyses of hydrothermally derived carbon materials from corn starch

Fuel Processing Technology

Volumn 153, Issue , 2016, Pages 43-49

  Zhao, Min ^a   Li, Bin ^a   Cai, Jia Xiao ^a   Liu, Chuan ^b   McAdam, K G ^b   Zhang, Ke ^a,c  

^a ZHENGZHOU TOBACCO RESEARCH INSTITUTE OF CNTC   (China)

^b Group Research and Development   (United Kingdom)

^c ZHENGZHOU UNIVERSITY   (China)

Author keywords

Hydrothermal carbonization; Kinetics; Microstructure; Pyrolysis; Thermogravimetric analysis

Indexed keywords

CARBONIZATION; CHARACTERIZATION; CHEMICAL ANALYSIS; COMBUSTION; ENZYME KINETICS; FOURIER TRANSFORM INFRARED SPECTROSCOPY; HYDROTHERMAL SYNTHESIS; INFRARED SPECTROSCOPY; KINETIC THEORY; KINETICS; MICROSTRUCTURE; PYROLYSIS; STARCH; TEMPERATURE; THERMOCHEMISTRY; X RAY PHOTOELECTRON SPECTROSCOPY;

CARBONACEOUS MATERIALS; FOURIER TRANSFORM INFRARED SPECTROMETRY; HIGH-TEMPERATURE COMBUSTION; HYDROTHERMAL CARBONIZATION; RESULTING MATERIALS; THERMOCHEMICAL PROPERTIES; THERMOGRAVIMETRIC MEASUREMENT; TWO-STEP CARBONIZATIONS;

THERMOGRAVIMETRIC ANALYSIS;

EID: 84982798891     PISSN: 03783820     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.fuproc.2016.08.002     Document Type: Article

References (38)

1. [1] Fitzer, E., Kochling, K.H., Boehm, H.P., Marsh, H., Recommended terminology for the description of carbon as a solid. Pure Appl. Chem. 67 (1995), 473–506.
2. [2] Román, S., Nabais, J.M.V., Laginhas, C., Ledesma, B., González, J.F., Hydrothermal carbonization as an effective way of densifying the energy content of biomass. Fuel Process. Technol. 103 (2012), 78–83.
3. [3] Branton, P., Lu, A.H., Schüth, F., The effect of carbon pore structure on the adsorption of cigarette smoke vapour phase compounds. Carbon 47 (2009), 1005–1011.
4. [4] Asada, T., Ohkubo, T., Kawata, K., Oikawa, K., Ammonia adsorption on bamboo charcoal with acid treatment. J. Health Sci. 52 (2006), 585–589.
5. [5] Sanderson, K., US biofuels: a field in ferment. Nature 444 (2006), 673–676.
6. [6] Schlamadinger, B., Marland, G., The role of forest and bioenergy strategies in the global carbon cycle. Biomass Bioenergy 10 (1996), 275–300.
7. [7] Serrano-Ruiz, J.C., Dumesic, J.A., Catalytic routes for the conversion of biomass into liquid hydrocarbon transportation fuels. Energy Environ. Sci. 4 (2011), 83–99.
8. [8] Titirici, M.M., White, R.J., Falco, C., Sevilla, M., Black perspectives for a green future: hydrothermal carbons for environment protection and energy storage. Energy Environ. Sci. 5 (2012), 6796–6822.
9. [9] Bergius, F., Die Anwendung hoher Dru¨cke bei chemischen Vorga¨ngen und eine Nachbildung des Entstehungsprozesses der Steinkohle, Knapp. Halle/Saale, 1913, 41–58.
10. [10] Brun, N., Sakaushi, K., Yu, L., Giebeler, L., Eckert, J., Titirici, M.M., Hydrothermal carbon-based nanostructured hollow spheres as electrode materials for high-power lithium-sulfur batteries. Phys. Chem. Chem. Phys. 15 (2013), 6080–6087.
11. [11] Sevilla, M., Fuertes, A.B., The production of carbon materials by hydrothermal carbonization of cellulose. Carbon 47 (2009), 2281–2289.
12. [12] Hoekman, S.K., Broch, A., Robbins, C., Hydrothermal carbonization (HTC) of lignocellulosic biomass. Energy Fuel 25 (2011), 1802–1810.
13. 2-gasification characteristics of hydrothermal carbonization solid fuel from municipal solid wastes. Fuel 181 (2016), 905–915.
14. [14] Peng, C., Zhai, Y.B., Zhu, Y., Xu, B.B., Wang, T.F., Li, C., Zeng, G.M., Production of char from sewage sludge employing hydrothermal carbonization: char properties, combustion behavior and thermal charateristics. Fuel 176 (2016), 110–118.
15. [15] Marynowski, L., Kubik, R., Uhl, D., Simoneit, B.R.T., Molecular composition of fossil charcoal and relationship with incomplete combustion of wood. Org. Geochem. 77 (2014), 22–31.
16. [16] Xiong, S., Zhang, S., Wu, Q., Guo, X., Dong, A., Chen, C., Investigation on cotton stalk and bamboo sawdust carbonization for barbecue charcoal preparation. Bioresour. Technol. 152 (2014), 86–92.
17. [17] Coats, A.W., Redfern, J.P., Kinetic parameters from thermogravimetric data. Nature 201 (1964), 68–69.
18. [18] Kök, M.V., Non-isothermal DSC and TG-DTG analysis of the combustion of Si̇lopi̇ asphaltites. J. Therm. Anal. Calorim. 88 (2007), 663–668.
19. [19] Garcia, R., Pizarro, C., Lavin, A.G., Bueno, J.L., Biomass proximate analysis using thermogravimetry. Bioresour. Technol. 139 (2013), 1–4.
20. [20] Channiwala, S.A., Parikh, P.P., A unified correlation for estimating HHV of solid, liquid and gaseous fuels. Fuel 89 (2002), 1051–1063.
21. [21] Miskolczi, N., Nagy, R., Hydrocarbons obtained by waste plastic pyrolysis: comparative analysis of decomposition described by different kinetic models. Fuel Process. Technol. 104 (2012), 96–104.
22. [22] Islam, M.A., Kabir, G., Asif, M., Hameed, B.H., Combustion kinetics of hydrochar produced from hydrothermal carbonisation of Karanj (Pongamia pinnata) fruit hulls via thermogravimetric analysis. Bioresour. Technol. 194 (2015), 14–20.
23. [23] Parshetti, G.K., Kent Hoekman, S., Balasubramanian, R., Chemical, structural and combustion characteristics of carbonaceous products obtained by hydrothermal carbonization of palm empty fruit bunches. Bioresour. Technol. 135 (2013), 683–689.
24. [24] Liu, Z., Balasubramanian, R., Hydrothermal carbonization of waste biomass for energy generation. Prog. Environ. Sci. 16 (2012), 159–166.
25. [25] Kök, M.V., Use of thermal equipment to evaluate crude oils. Thermochim. Acta 214 (1993), 315–324.
26. [26] Titirici, M.M., Antonietti, M., Baccile, N., Hydrothermal carbon from biomass: a comparison of the local structure from poly-to monosaccharides and pentoses/hexoses. Green Chem. 10 (2008), 1204–1212.
27. [27] Zhao, S., Wang, C., Chen, M., Shi, Z., Preparation of carbon sphere from corn starch by a simple method. Mater. Lett. 62 (2008), 3322–3324.
28. [28] Zheng, M., Liu, Y., Jiang, K., Xiao, Y., Yuan, D., Alcohol-assisted hydrothermal carbonization to fabricate spheroidal carbons with a tunable shape and aspect ratio. Carbon 48 (2010), 1224–1233.
29. 13C NMR investigations. J. Chem. Phys. C, 2009, 9644–9654.
30. [30] Budarin, V., Clark, J.H., Hardy, J.J.E., Luque, R., Milkowski, K., Tavener, S.J., Wilson, A.J., Starbons: new starch-derived mesoporous carbonaceous materials with tunable properties. Angew. Chem. Int. Ed. 118 (2006), 3866–3870.
31. 13C solid state NMR. Langmuir 27 (2011), 14460–14471.
32. [32] Sevilla, M., Fuertes, A.B., Chemical and structural properties of carbonaceous products obtained by hydrothermal carbonization of saccharides. Chem. Eur. J. 15 (2009), 4195–4203.
33. [33] Stankovich, S., Dikin, D.A., Piner, R.D., Kohlhaas, K.A., Kleinhammes, A., Jia, Y.Y., Wu, Y., Nguyen, S.T., Ruoff, R.S., Synthesis of graphene-based nanosheets via chemical reduction of exfoliated graphite oxide. Carbon 45 (2007), 1558–1565.
34. [34] Kubo, S., Tan, I., White, R.J., Antonietti, M., Titirici, M.M., Template synthesis of carbonaceous tubular nanostructures with tunable surface properties. Chem. Mater. 22 (2010), 6590–6597.
35. 3H sites. Carbon 74 (2014), 333–345.
36. 13C-solid state nuclear magnetic resonance. Green Chem. 16 (2014), 4839–4869.
37. 13C nuclear magnetic resonance (NMR) spectroscopy. Energy Fuel 25 (2011), 388–397.
38. [38] Falco, C., Baccile, N., Titirici, M.M., Morphological and structural differences between glucose, cellulose and lignocellulosic biomass derived hydrothermal carbons. Green Chem. 13 (2011), 3273–3281.