Sains Malaysiana 40(3)(2011): 221–226

 

Nano Transition Metal Sulfide Catalyst for Solvolysis Liquefaction of Soda Lignin

(Pemangkin Sulfida Logam Peralihan Bersaiz-Nano untuk Pencecairan Solvolisis Soda Lignin)

 

Fei-Ling Pua, Chin-Hua Chia, Sarani Zakaria*, Soon-Keong Neoh & Tze-Khong Liew

School of Applied Physics, Faculty of Science and Technology

Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor D.E., Malaysia

 

Received: 25 January 2010 / Accepted: 3 September 2010

 

ABSTRACT

 

Solvolysis liquefaction of soda lignin in the presence of various transition metal sulfide catalysts was studied to investigate the catalyst effects on the oil and gas yields, conversion rate and higher heating value (HHV) of oil. Nanosized copper sulfide, iron sulfide and molybdenum sulfide were successfully synthesized via a simple hydrothermal method under reaction temperature 200°C for 90 min. The addition of transition metal sulfide based catalysts (CuS, MoS2 and FeS2) enhanced both production of the oils and gas and the higher heating value (HHV) of oil products. A high oil and gas yields of 82.1% and 2890 cm3 was obtained with MoS2 at 250°C for 60 min. Elemental analyses for the oils revealed that the liquid products have much higher heating values than the crude soda lignin powder.

 

Keywords: Catalyst; higher heating value; hydrothermal; soda lignin; solvolysis liquefaction

 

ABSTRAK

 

Pencecairan solvolisis soda lignin dengan kehadiran pelbagai mangkin sulfida logam peralihan telah dikaji tentang kesan mangkin ke atas hasil minyak dan gas, kadar penukaran dan nilai pembakaran tinggi (HHV) minyak solvolisis. Sulfida kuprum, sulfida ferum dan sulfida molibdenum yang bersaiz nano telah berjaya disintesis melalui kaedah hidroterma di bawah suhu 200°C dalam masa tindak balas sepanjang 90 minit. Penggunaan mangkin sulfida logam peralihan (CuS, MoS2 and FeS2) dalam proses solvolisis telah meningkatkan kadar hasil minyak serta gas dan produk minyak telah berjaya mencapai nilai pembakaran (HHV) yang tinggi. Hasil minyak dan gas yang tinggi iaitu: 82.1% and 2890 cm3 telah diperoleh dengan penggunaan mangkin MoS2 di bawah suhu 250°C selama 60 minit. Analisis unsur untuk minyak solvolisis menunjukkan produk cecair daripada pencecairan solvolisis mempunyai nilai pembakaran tinggi (HHV) yang lebih tinggi berbanding dengan serbuk soda lignin.

 

Kata kunci: Hidroterma; mangkin; nilai pembakaran tinggi; pencecairan solvolisis; soda lignin

 

REFERENCES

 

Alejandra, G., Jose, C.B., Luis, E. & Miguel Jose, Y. 2008. Characterization of low dimensional molybdenum sulfide nanostructures. Materials Characterization 59: 204-212.

Balaz, P., Boldizarova, E., Godocikova, E. & Briancin, J. 2003. Mechanochemical route for sulphide nanoparticles preparation. Materials Letters 57: 1585-1589.

Huber, G.W., Iborra. S. & Corma, A. 2006. Synthesis of transportation fuels from biomass: Chemistry, catalysts and engineering. Chemical Review 106: 4044-4098.

Hu, H., Bai, J., Guo, S. & Chen, G. 2002. Coal liquefaction with in situ impregnated Fe2(MoS4)3 bimetallic catalyst. Fuel 81: 1521-1524.

Liao, X.H., Wang, H., Zhu, J.J. & Chen, H.Y. 2001. Preparation of Bi2S3 nanorods by microwave irradiation. Materials Research Bulletin 36: 2339-2346.

Lora, J.H. & Glasser, W.G. 2002. Recent industrial applications of lignin: A sustainable alternative to nonrenewable materials. Journal of Polymer and the Environment 10: 39-48.

Ma, L., Chen, W.-X., Li, H., Zheng, Y.-F. & Xu, Z.-D. 2008. Ionic liquid-assisted hydrothermal synthesis of MoS2 microspheres. Materials Letters 62: 797-799.

Mointeiro, O.C. & Trindade, T. 2004. Synthesis of molybdenum (IV) disulfide using a single-source method. Materials Research Bulletin 39: 357-363.

Qian, Y., Zuo, C. Tian, J. & He, J. 2007. Structural analysis of bio-oils from sub- and supercritical water liquefaction of woody biomass. Energy 32: 196-202.

Qin, A.M., Fang, Y.P., Ou, H.D., Liu, H.Q. & Su, C.Y. 2005. Formation of various morphologies of covellite copper sulfide submicron crystals by a hydrothermal method without surfactant. Crystal Growth and Design 5: 855-860.

Subba Reddy, Ch.V., Edwin H, W.J., Wen, C. & Mho, S. 2008. Hydrpthermal synthesis of MoO3 nanobelts utilizing poly(ethylene glycol). Journal of Power Sources 183: 330-333.

Tian, D., Sharma, R.K., Stiller, A.H., Stinespring, C.D. & Dadyburjor, D.B. 1996. Direct liquefaction of coal using ferric-sulfide-based, mixed-metal catalysts containing Mg or Mo. Fuel 75(6): 751-758.

Zou, J., Zhang, J, Zhang, B., Zhao, P. & Huang, K. 2007. Low-temperature synthesis of copper sulfide nano-crystals of novel morphologies by hydrothermal process. Materials Letters 61: 5029-5032.

 

*Corresponding author; email: sarani@ukm.my

 

 

 

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