Abstract:
Thermochemical conversion of wood sawdust from two invasive arboreal species (Prosopis ruscifolia and Parkinsonia aculeata) into valuable products is explored to provide novel possible means of spread control attempting to their use as alternative, easily renewable bio-resources for bioenergy generation and activated carbons production. Rapid pyrolysis of both wood species is examined to assess the feasibility of their conversion into energy products. Yields of the three kinds of pyrolysis products, comprising bio-oil, non-condensable gas, and bio-char, are determined from experiments performed in a bench-scale installation at 500 °C. The wood species noticeably affects yields and distributions of the pyrolysis products. Main physicochemical characteristics and higher heating value (HHV) of the products generated from Prosopis ruscifolia, leading to higher bio-oil yield (~42%) than Parkinsonia aculeata, are determined. All the products show potentialities for energy applications. The bio-oil, further upgraded, could be employed as a liquid fuel with characteristics similar to those of fuel-oil, whereas the low heating value-gas evolved with pyrolysis course, mostly composed by CO2, CO, CH4 and H2, might contribute to energy sustainability of the process. In turn, the bio-char (HHV≈ 27 MJ/kg) has potential as environmentally friendly solid bio-fuel. Kinetic measurements for the pyrolysis of the two wood species are also carried out by non-isothermal thermogravimetric analysis from room temperature up to 500 °C. An overall first-order decomposition model enables to properly represent kinetic data for both species over the whole temperature range. Differences in pyrolytic reactivity are reflected in the estimated kinetic parameters. On the other hand, use of wood sawdust from the two species as precursor of activated carbons targeted at wastewater treatment is investigated. For this purpose, the phosphoric acid activation process is applied at pre-established moderate conditions (acid/precursor weight ratio of 2, 450 °C, 0.5 h). The activation atmosphere involved in the thermal treatment stage of the process is in situ modified to examine its influence on the development of porous structures, surface chemistry, and adsorptive behaviour of the resulting activated carbons. Either a self-generated atmosphere, flowing air or nitrogen is used. The activation atmosphere and the wood species have a marked influence on the characteristics of the derived carbons. Those developed from Prosopis ruscifolia wood in the self-generated atmosphere show higher BET surface area and total pore volume (2281 m2/g, 1.7 cm3/g) than the ones obtained under flowing air (1638 m2/g and 1.3 cm3/g), although the latter possess a higher total content of surface acidic/polar oxygen groups (2.2 meq/g) than the former (1.5 meq/g). Textural characteristics of P. ruscifolia-based activated carbons are superior to those for the carbons developed from P. aculeata wood in the self-generated atmosphere (968 m2/g, 0.70 cm3/g) and flowing N2 (1103 m2/g, 0.75 cm3/g). These samples have total contents of surface acidic/polar oxygen functionalities of 1.9 meq/g and 1.7 meq/g, respectively. The ability of the activated carbons in removing representative toxic metal ions, oxo-anions, and organic compounds is examined from batch assays using dilute aqueous solutions as models of wastewater. Adsorption isotherms of Cu[II] ion onto P. ruscifolia-based activated carbons are determined and properly described by the Langmuir model. Maximum sorption capacity (Xm) for the air-derived carbons (Xm= 0.44 mmol/g) almost duplicates the value for those obtained in the self-generated atmosphere (Xm= 0.24 mmol/g), pointing to a predominant effect of the surface acidic functionalities on metal sequestering behaviour. Adsorption isotherms of salicylic acid onto the air-derived carbons are also ascertained, and satisfactorily fitted to the Langmuir model. On the other hand, effectiveness of the P. aculeata-based activated carbons in removing individual nitrate ion, phenol, and methylene blue at pre-established equilibrium conditions is comparatively investigated. High removal levels are attained for the organics (~ 90% and 100% for phenol and methylene blue, respectively), but nitrate removal is low (≤ 40%). Removal effectiveness of these carbons is inversely related to water solubility of the solutes and is slightly affected by the activation atmosphere. Accordingly, effective activated carbons of potential applicability in tertiary wastewater treatment may be developed from the two invasive species, as suitable, alternative precursors, by phosphoric acid activation at moderate conditions. © 2012 by Nova Science Publishers, Inc. All rights reserved.
Registro:
| Documento: |
Parte de libro
|
| Título: | Thermochemical processing of wood from invasive arboreal species for sustainable bioenergy generation and activated carbons production |
| Autor: | Cukierman, A.L.; Nunell, G.V.; Fernández, M.E.; De Celis, J.; Kim, M.R.; Gurevich Messina, L.; Bonelli, P.R. |
| Filiación: | Depto. de Industrias, Universidad de Buenos Aires Int. Güiraldes, Ciudad Universitaria, Buenos Aires, Argentina
Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET), Buenos Aires, Argentina
Cátedra de Farmacotecnia II. Depto. de Tecnología Farmacéutica, Facultad de Farmacia y Bioquímica, Universidad de Buenos Aires, Buenos Aires, Argentina
|
| Año: | 2012
|
| Página de inicio: | 1
|
| Página de fin: | 45
|
| Título revista: | Invasive Species: Threats, Ecological Impact and Control Methods
|
| Título revista abreviado: | Invasive Species: Threat., Ecol. Impact and Control Methods
|
| Registro: | https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_97816194_v_n_p1_Cukierman |
Referencias:
- Bandosz, T.J., Activated carbon surfaces in environmental remediation (2006), Academic Press, London, UK; Basso, M.C., Cerrella, E.G., Cukierman, A.L., Activated carbons developed from a rapidly renewable biosource for removal of cadmium (II) and nickel (II) ions from dilute aqueous solutions (2002) Ind. Eng. Chem. Res., 41, pp. 180-189
- Basso, M.C., Cukierman, A.L., Arundo donax-based activated carbons for aqueous-phase adsorption of volatile organic compounds (2005) Ind. Eng. Chem. Res., 44, pp. 2091-2100
- Basso, M.C., Cerrella, E.G., Buonomo, E., Bonelli, P., Cukierman, A.L., Thermochemical conversion of Arundo donax into useful solid products (2005) Energy Sources, 27, pp. 1429-1438
- Basso, M.C., Cukierman, A.L., Wastewater treatment by chemically activated carbons from giant reed: Effect of the activation atmosphere on properties and adsorptive behavior (2006) Sep. Sci.Technol., 41, pp. 149-156
- Benaddi, H., Legras, D., Rouzaud, J.N., Beguin, F., Influence of the atmosphere in the chemical activation of wood by phosphoric acid (1998) Carbon, 36 (3), pp. 306-309
- Blanco Castro, J., Bonelli, P.R., Cerrella, E.G., Cukierman, A.L., Phosphoric acid activation of agricultural residues and bagasse from sugar cane: influence of the experimental conditions on adsorption characteristics of activated carbons (2000) Ind. Eng. Chem. Res., 39, pp. 4166-4172
- Bonelli, P., Della Rocca, P., Cerrella, E.G., Cukierman, A.L., Effect of pyrolysis temperature on composition, surface properties and thermal degradation rates of Brazil nut shells (2001) Bioresource Technology, 76, pp. 15-22
- Bonelli, P., Cerrella, E.G., Cukierman, A.L., Slow pyrolysis of nutshells: characterization of derived chars and of process kinetics (2003) Energy Sources, 25, pp. 767-778
- Bonelli, P., Buonomo, E., Cukierman, A.L., Pyrolysis of sugarcane bagasse and co-pyrolysis with an argentinean subbituminous coal (2007) Energy Sources Part A, 29, pp. 731-740
- Bottani, E.J., Tascón, J.M.D., Overview of carbon materials in relation to adsorption (2008) Adsorption by Carbons, pp. 15-49. , Elsevier, Oxford, UK
- Bozell, J.J., Feedstocks for the future - Biorefinery production of chemicals from renewable carbon (2008) Clean, 36, pp. 41-47
- Bridgwater, A.V., Review of fast pyrolysis of biomass and product upgrading (2011) Biomass and Bionergy, , In press, doi:10.1016/j.biombioe.2011.01.048
- Butler, E., Devlin, G., Meier, D., McDonnell, K., A review of recent laboratory research and commercial developments in fast pyrolysis and upgrading (2011) Renewable and Sustainable Energy Reviews, 15, pp. 4171-4186
- Channiwala, S.A., Parikh, P.P., A unified correlation for estimating HHV of solid, liquid and gaseous fuels (2002) Fuel, 81, pp. 1051-1063
- Cochard, R., Jackes, B.R., Seed ecology of the invasive tropical tree Parkinsonia aculeata (2005) Plant Ecology, 180, pp. 13-31
- Cooney, D.O., Adsorption design for wastewater treatment (1999), CRC Press LLC, Boca Raton, USA; Cordero, T., Marquez, F., Rodríguez Mirasol, T., Rodríguez, J.J., Predicting heating values of lignocellulosics and carbonaceous materials from proximate analysys (2001) Fuel, 80, pp. 1567-1571
- Cukierman, A.L., Metal ion biosorption potential of lignocellulosic biomasses and marine algae for wastewater treatment (2007) Adsorption Science & Technology, 25 (3-4), pp. 227-244
- De Celis, J., Amadeo, N.E., Cukierman, A.L., In situ modification of activated carbons developed from a native invasive wood on removal of trace toxic metals from wastewater (2009) Journal of Hazardous Materials, 161, pp. 217-223
- Della Rocca, P.A., Cerrella, E.G., Bonelli, P.R., Cukierman, A.L., Pyrolysis of hardwood residues: On kinetics and chars characterization (1999) Biomass & Bioenergy, 16, pp. 79-88
- Demirbas, A., Agricultural based activated carbons for the removal of dyes from aqueous solutions: A review (2009) Journal of Hazardous Materials, 167, pp. 1-9
- Di Blasi, C., Signorelli, G., Di Russo, C., Rea, G., Product distribution from pyrolysis of wood and agricultural residues (1999) Ind. Eng. Chem. Res., 38, pp. 2216-2224
- Di Blasi, C., Modeling chemical and physical processes of wood and biomass pyrolysis (2008) Progress in Energy and Combustion Science, 34, pp. 47-90
- Dubey, S.P., Dwivedi, A.D., Sillanpää, M., Gopal, K., Artemisia vulgaris-derived mesoporous honeycomb-shaped activated carbon for ibuprofen adsorption (2010) Chemical Engineering Journal, 165, pp. 537-544
- Encinar, J.M., Beltrán, F.J., González, J.F., Moreno, M.J., Pyrolysis of maize, sunflower, grape and tobacco residues (1997) Journal of Chemical Technology and Biotechnology, 70 (4), pp. 400-410
- Encinar, J.M., Gónzalez, J.F., Martínez, G., Romám, S., Jerusalem artichoke pyrolysis: Energetic evaluation (2009) Journal of Analytical and Applied Pyrolysis, 85, pp. 294-300
- Fierro, V., Torné-Fernández, V., Celzard, A., Montané, D., Influence of the demineralisation on the chemical activation of Kraft lignin with orthophosphoric acid (2007) Journal of Hazardous Materials, 149, pp. 126-133
- Garcia-Perez, M., Wang, X.S., Shen, J., Rhodes, M.J., Tian, F., Lee, W.-J., Wu, H., Li, C., Fast pyrolysis of oil mallee woody biomass: Effect of temperature on the yield and quality of pyrolysis products (2008) Ind. Eng. Chem. Res., 47, pp. 1846-1854
- Girgis, B.S., Ishak, M., Activated carbon from cotton stalks by impregnation with phosphoric acid (1999) Materials Letters, 39, pp. 107-114
- Girgis, B.S., Soliman, A.M., Fathy, N.A., Development of micro-mesoporous carbons from several seed hulls under varying conditions of activation (2011) Microporous and Mesoporous Materials, 142, pp. 518-525
- González, J.F., Ramiro, A., González-García, C.M., Gañán, J., Encinar, J.M., Sabio, E., Rubiales, J., Pyrolysis of almond shells. Energy applications of fractions (2005) Ind. Eng. Chem. Res., 44, pp. 3003-3012
- González, J., Kim, M.R., Buonomo, E., Bonelli, P., Cukierman, A.L., Pyrolysis of biomass from sustainable energy plantations: Effect of mineral matter reduction on kinetics and charcoal pore structure (2008) Energy Sources Part A, 30, pp. 809-817
- Guo, Y., Rockstraw, D.A., Activated carbons prepared from rice hull by one-step phosphoric acid activation (2007) Microporous and Mesoporous Materials, 100, pp. 12-19
- Gupta, R., Demirbas, A., Gasoline, diesel, and ethanol biofuels from grasses and plants (2010), Cambridge University Press. New York, USA; Ioannidou, O., Zabaniotou, A., Antonakou, E.V., Papasizi, K.M., Lappas, A.A., Athanassiou, C., Investigating the potential for energy, fuel, materials and chemicals production from corn residues (cobs and stalks) by non-catalytic and catalityc pyrolysis in two reactor configurations (2009) Renewable and Sustainable Energy Reviews, 13, pp. 750-762
- Jagtoyen, M., Derbyshire, F., Activated carbons from yellow poplar and white oak by H3PO4 activation (1998) Carbon, 36, pp. 1085-1097
- Keller, R.P., Geist, J., Jeschke, J.M., Kühn, I., Invasive species in Europe: Ecology, status, and policy (2011) Environmental Sciences Europe, 23, p. 23. , doi:10.1186/2190-4715-23-23
- Khezami, L., Chetouani, A., Taouk, B., Capart, R., Production and characterisation of activated carbon from wood components in powder: Cellulose, lignin, xylan (2005) Powder Technology, 157, pp. 48-56
- Mortensen, P.M., Grunwaldt, J.-D., Jensen, P.A., Knudsen, K.G., Jensen, A.D., A review of catalytic upgrading of bio-oil to engine fuels (2011) Applied Catalysis A: General, 407, pp. 1-19
- Nabais, J.V., Carrott, P., Ribeiro Carrott, M.M.L., Luz, V., Ortiz, A.L., Influence of preparation conditions in the textural and chemical properties of activated carbons from a novel biomass precursor: The coffee endocarp (2008) Bioresource Technology, 99, pp. 7224-7231
- Nabais, J.V., Laginhasa, C., Carrott, P., Ribeiro Carrott, M.M.L., Thermal conversion of a novel biomass agricultural residue (vine shoots) into activated carbon using activation with CO2 (2010) Journal of Analytical and Applied Pyrolysis, 87, pp. 8-13
- Özçimen, D., Ersoy-Meriçboyu, A., Characterization of biochar and bio-oil samples obtained from carbonization of various biomass materials (2010) Renewable Energy, 35 (6), pp. 1319-1324
- Park, Y.-K., Yoo, M.L., Lee, H.W., Park, S.H., Jung, S.-C., Park, S.-S., Kim, S.-C., Effects of operation conditiones on pyrolysis characteristics of agricultural residues (2011) Renewable Energy, , In press, doi:10.1016/j.renene.2011.08.050
- Patrick, J.W., Porosity in carbons: Characterization and applications (1995), John Wiley & Sons, Inc. New York, USA; Puziy, A.M., Poddubnaya, O.I., Martínez-Alonso, A., Suarez-García, F., Tascón, J.M.D., Synthetic carbons activated with phosphoric acid I, Surface chemistry and ion binding properties (2002) Carbon, 40, pp. 1493-1505
- Puziy, A.M., Poddubnaya, O.I., Martínez-Alonso, A., Castro-Muñiz, A., Suarez-García, F., Tascón, J.M.D., Oxygen and phosphorus enriched carbons from lignocellulosic material (2007) Carbon, 45, pp. 1941-1950
- Qu, T., Guo, W., Shen, L., Xiao, J., Zhao, K., Experimental study of biomass pyrolysis based on three major components: Hemicellulose, cellulose, and lignin (2011) Ind. Eng. Chem. Res., 50, pp. 10424-10433
- Ramos, M.E., Gonzalez, J.D., Bonelli, P.R., Cukierman, A.L., Effect of process conditions on physicochemical and electrical characteristics of denim-based activated carbon cloths (2007) Ind. Eng. Chem. Res., 46, pp. 1167-1173
- Ramos, M.E., Bonelli, P.R., Blacher, S., Ribeiro Carrott, M.M.L., Carrot, P.J.M., Cukierman, A.L., Effect of the activating agent on physico-chemical and electrical properties of activated carbon cloths developed from a novel cellulosic precursor (2011) Colloids and Surfaces A: Physicochemical and Engineering Aspects, 378, pp. 87-93
- Richardson, D.M., Rejmánek, M., Trees and shrubs as invasive alien species - A global review (2011) Diversity and Distributions, 17, pp. 788-809
- Rivera-Utrilla, J., Sánchez-Polo, M., Gómez-Serrano, V., Álvarez, P.M., Alvim-Ferraz, M.C.M., Dias, J.M., Activated carbon modifications to enhance its water treatment applications (2011) An overview. Journal of Hazardous Materials, 187, pp. 1-23
- Rodríguez-Reinoso, F., Production and application of activated carbon (2002) Handbook of Porous Solids, pp. 1766-1827. , Wiley-VCH, Weinheim, Germany
- The economics of activated carbon report (2008), http://www.roskill.com/reports/activated, Roskill Information Services, 8th Edition, Roskill Information Services Ltd; Saidur, R., Abdelaziz, E.A., Demirbas, A., Hossain, M.S., Mekhilef, S., A review on biomass as a fuel for boilers (2011) Renewable and Sustainable Energy Reviews, 15 (5), pp. 2262-2289
- Schell, C., Riley, C., Peterson, G.R., Pathways for development of a biorenewables industry (2008) Bioresource Technology, 99 (12), pp. 5160-5164
- Silvestre-Albero, A., Gonçalves, M., Itoh, T., Kaneko, K., Endo, M., Thommes, M., Rodríguez-Reinoso, F., Silvestre-Albero, J., Well-defined mesoporosity on lignocellulosic-derived activated carbons (2012) Carbon, 50, pp. 66-72
- Telmo, C., Lousada, J., Heating values of wood pellets from different species (2011) Biomass and Bioenergy, 35 (7), pp. 2634-2639
- Granular activated carbon: adsorption and regeneration (2000), U.S. Environmental Protection Agency. Wastewater Technology Fact Sheet, U.S. EPA 832-F-00-017. Office of Water. Washington, D.C; Vernersson, T., Bonelli, P., Cerrella, G., Cukierman, A.L., Arundo cane as a precursor for activated carbon preparation by phosphoric acid activation (2002) Bioresource Technology, 83, pp. 95-104
- White, J.E., James Catallo, W., Legendre, B.L., Biomass pyrolysis kinetics: A comparative critical review with relevant agricultural residue case studies (2011) Journal of Analytical and Applied Pyrolysis, 91, pp. 1-33
- Wongsiriamnuay, T., Tippayawong, N., Non-isothermal pyrolysis characteristics of giant sensitive plants using thermogravimetric analysis (2010) Bioresource Technology, 101, pp. 5638-5644
- Yates, E.D., Levia, D.F., Williams, C.L., Recruitment of three non-native invasive plants into a fragmented forest in southern Illinois (2004) Forest Ecology and Management, 190, pp. 119-130
- Yoder, J., Galinato, S., Granatstein, D., García-Pérez, M., Economic tradeoff between biochar and bio-oil production via pyrolysis (2011) Biomass & Bioenergy, 35, pp. 1851-1862
- Zhang, Q., Chang, J., Wang, T., Xu, Y., Review of biomass pyrolysis oil properties and upgrading research (2007) Energy Conversion and Management, 48, pp. 87-92
Citas:
---------- APA ----------
Cukierman, A.L., Nunell, G.V., Fernández, M.E., De Celis, J., Kim, M.R., Gurevich Messina, L. & Bonelli, P.R.
(2012)
. Thermochemical processing of wood from invasive arboreal species for sustainable bioenergy generation and activated carbons production. Invasive Species: Threats, Ecological Impact and Control Methods, 1-45.
Recuperado de https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_97816194_v_n_p1_Cukierman [ ]
---------- CHICAGO ----------
Cukierman, A.L., Nunell, G.V., Fernández, M.E., De Celis, J., Kim, M.R., Gurevich Messina, L., et al.
"Thermochemical processing of wood from invasive arboreal species for sustainable bioenergy generation and activated carbons production"
. Invasive Species: Threats, Ecological Impact and Control Methods
(2012) : 1-45.
Recuperado de https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_97816194_v_n_p1_Cukierman [ ]
---------- MLA ----------
Cukierman, A.L., Nunell, G.V., Fernández, M.E., De Celis, J., Kim, M.R., Gurevich Messina, L., et al.
"Thermochemical processing of wood from invasive arboreal species for sustainable bioenergy generation and activated carbons production"
. Invasive Species: Threats, Ecological Impact and Control Methods, 2012, pp. 1-45.
Recuperado de https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_97816194_v_n_p1_Cukierman [ ]
---------- VANCOUVER ----------
Cukierman, A.L., Nunell, G.V., Fernández, M.E., De Celis, J., Kim, M.R., Gurevich Messina, L., et al. Thermochemical processing of wood from invasive arboreal species for sustainable bioenergy generation and activated carbons production. Invasive Species: Threat., Ecol. Impact and Control Methods. 2012:1-45.
Available from: https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_97816194_v_n_p1_Cukierman [ ]
