dc.contributor | González Mariño, Gloria Eugenia | |
dc.date.accessioned | 2013-05-23T16:49:39Z | |
dc.date.available | 2013-05-23T16:49:39Z | |
dc.date.created | 2013-05-23T16:49:39Z | |
dc.date.issued | 2009 | |
dc.identifier | Pimentel D, Harman R, Pacenza M, Pecarsky J, Pimentel M. Natural resources and an optimum human population. Population and Environment. (1994); 15 (5): 347-369 | |
dc.identifier | FAO Statistical División. Stadistical data. FAO Quarterly Bulletin of Statistics (1992); 5: 1 | |
dc.identifier | Colombia. Departamento Nacional de Planeación. Plan 2019: Visión Colombia II Centenario. Bogotá: El Departamento; 2006 | |
dc.identifier | Colombia. Ministerio de Agricultura y Desarrollo Rural. Apuesta Exportadora Agropecuaria 2006-2019. Bogotá: El Ministerio; 2006 | |
dc.identifier | Pimentel D, Harvey C, Resosudarmo P, Sinclair K, Kurz D, McNair M et al. Environmental Costo f soil erosion and conservation benefits. Science (1995); 267 (5201): 1117-1223 | |
dc.identifier | Barclay WR, Lewin RA. Microalgal polysaccharide production for the conditioning of agricultural soils. Plant Soil (1985); 88 (2): 159-169 | |
dc.identifier | Vitousek PM, Mooney HA, Lubchenco J, Melillo JM. Human domination of Earth’s ecosystems. Science (1997); 277 (5323): 494-499 | |
dc.identifier | Wardle DA, Bardgett RD, Klironomos JN, Setälä, van der Putten W, Wall DH. Ecological linkages between aboveground and belowground biota. Science (2004); 304 (5677): 1629-1633 | |
dc.identifier | McNeill JR, Winiwarter V. Breaking the sod: Humankind, history, and soil. Science (2004); 304 (5677): 1627-1629 | |
dc.identifier | McNeill JR. Something new under the sun: an environmental history of the 20th – century World. New York: Norton; 2000. | |
dc.identifier | Barrow JC. Land Degradation. Cambridge: Cambridge University Press; 1991. | |
dc.identifier | Mann ChC. El futuro está en la tierra que yace a nuestros pies. National Geographic en Español (2008); 23 (3): 2-27 | |
dc.identifier | Sanchez PA, Buol SW. Soils of the tropics and the World food crisis. Science (1975); 188 (4188): 598-603 | |
dc.identifier | Larson WE, Pierce FJ, Dowdy RH. The treat of soil erosion to long-term crop production. Science (1983); 219 (4584): 458-465 | |
dc.identifier | Chaney K, Swift SR, The influence of organic matter on agrégate stability in some British soils. Journal of Soil Science (1984); 45 (): 273-283 | |
dc.identifier | Allison FE. Soil organic Matter and Its role in crop production. New York: Elsevier; 1973. | |
dc.identifier | Grant WD, Long PE. Microbiología ambiental. Zaragoza: Acribia; 1989 | |
dc.identifier | Pimentel D, Garnick E, Berkowitz A, Jacobson S, Napolitano S, Black P et al. Environmental quality and natural biota. BioScience (1980); 30: 750-755 | |
dc.identifier | Lewin RA. The use of algae as soil conditioners. Centros Invest. Baja Calif. Scripps. Inst. Oceanogr, 3 (1977), 33-35. | |
dc.identifier | Foster RC. Polysaccharides in soil fabrics. Science (1981); 214 (4521): 665-667 | |
dc.identifier | Metting B. The systematics and ecology of soil algae. The Botanical Review (1981); 47 (2): 195-312 | |
dc.identifier | Mazor G, Kidron GJ, Vonshak A, Abeliovich A. The role of cyanobacterial exopolysaccharides in structuring desert microbiol crusts. FEMS Microb Ecol (1996); 21: 121-130 | |
dc.identifier | Apte SK, Thomas J. Possible reclamation of coastal soil salinity using halotolerant nitrógeno-fixing cyanobacteria. Planta and Soil (1997); 189: 205-211 | |
dc.identifier | Kaushik BD, Venkataraman GS. Reclamative capacity of blue-green algae in saline and sodic soils. En: Proceedings of the National Symposium on Biological Nitrogen Fixation, Department of Atomic Energy. Bombay. p. 378-389 | |
dc.identifier | Ashraf M, Hasnain S, Berge O. Effecto of exo-polysaccharides producing bacterial inoculation on growth of roots of wheat (Triticum aestivum) plants grown in a saltaffected soil. IJEST (2006); 3: 43-51 | |
dc.identifier | Cohen Z. Products from microalgae. En: Richmond A, editor. Handbook of microalgae mass culture. Florida: CRC Press, 1986. p. 421-454 | |
dc.identifier | Ördög V, Stirk WA, Lenobel R, Bancírová M, Strnad M, van Staden J, Szigeti J, Németh L. Screening microalgae for some potentially useful agricultural and pharmaceutical secondary metabolites. Journal of Applied Phycology (2004); 16 (4): 309-314 | |
dc.identifier | Roeselers G, van Loosdrecht MCM, Muyzer G. Phototrophic biofilms and their potencial applications. Journal of Applied Phycology (2008); 20 (3): 227-235 | |
dc.identifier | Borowitzka MA. Microalgae as sources of fine chemicals. Current Microbiology (1986); 3: 372-375 | |
dc.identifier | Bubrik P. Production of astaxanthin from Haematococcus. Bioresource Technology (1991); 38 (2-3): 237-239 | |
dc.identifier | Pulz O. Photobioreactors: production Systems for phototrophic microorganisms.
Applied Microbiology and Biotechnology (2001); 57 (3): 287-293 | |
dc.identifier | Banerjee A, Sharma R, Chisti Y, Banerjee UC. Botryococcus braunii; a renewable
source of hydrocarbons and other chemicals. Critical Reviews in Biotechnology (2002);
22: 245-279 | |
dc.identifier | Spolaore P, Joanniss-Cassan C, Duran E, Isambert A. Commercial applications of
microalgae. Journal of Bioscience an Bioengineering (2006); 101 (2): 87-96 | |
dc.identifier | Cardozo KHM, Guaratini T, Barros MP, Falcao VR, Tonon AP, Lopes NP et al.
Metabolites from algae with economical impact. Comparative Biochemistry and
Physiology (2007); C146 (1-2): 60-78 | |
dc.identifier | Dos Santos MD, Guarantini T, Lopes JLC, Colepicolo P, Lopes NP. Plant cell and
microalgae culture. En: Modern Biotechnology in Medicinal Chemistry and Industry
(2005). Research signpost, Kerala, India | |
dc.identifier | Stirk WA, Ördög V, Van Staden J, Jäger K. Cytokinin- and auxina-like activity in
Cyanophyta and microalgae. Journal of Applied Phycology (2002); 14 (3): 215-221 | |
dc.identifier | Augier, H. Les hormones des algues. Etat actuel des connaissances. VII-Applications,
conclusión, bibliographie. Bot. Mar. 21: 175-197. | |
dc.identifier | Buggeln RG. Morphogenesis and growth regulators. En: Lobban CS y Winne MJ,
editors. The biology of seaweeds. Berkeley: University of California Press; 1981. p.
627-660 | |
dc.identifier | Jacobs WP. Are angiosperm hormones present in, and used as hormones by, algae?
En: Bopp M, editor. Plant growth substances 1983. Berlín: Springer-Verlag; 1986. p.
249-256 | |
dc.identifier | Evans LV, Trewavas AJ. Is algal development controlled by plant growth substances?
Journal of Phycology (1991); 27: 322-326 | |
dc.identifier | Bradley PM. Plant hormones do have a role in controlling growth and development of
algae. Journal of Phycology (1991); 27: 317-321 | |
dc.identifier | Kefeli VI, Dashek WV. Non-hormonal stimulators and inhibitors of plant growth and
development. Biol. Rev. (1984); 59: 273-288 | |
dc.identifier | Martínez Sancho Ma
E, Jiménez Castillo JM, El Yousfi F. Photoautotrophic
consumption of phosphorus by Scenedesmus obliquus in a continuous culture –
Influence of light intensity. Process Biochemistry (1999); 34: 811-818 | |
dc.identifier | Sánchez JF, Fernández JM, Acién FG, Rueda A, Pérez-Parra J, Molina E. Influence of
culture conditions on the productivity and lutein content of the new strain
Scenedesmus almeriensis. Process Biochemistry (2008); 43: 398-405 | |
dc.identifier | Stirk WA, Ördög V, van Staden J, Jäger K. Cytokinin-and-auxin-like activity in
Cyanophyta and microalgae. Journal of Applied Phycology (2002); 14: 215-221 | |
dc.identifier | Bailey D, Mazurak AP, Rosowski JR. Aggregation of soil particles by algae. Journal of
Phycology (1973); 9: 99-101 | |
dc.identifier | Masojídek J, Koblízek M, Torzillo G. Photosynthesis in microalgae. En: Richmond A,
editor. Handbook of microalgal culture: biotechnology and applied phycology, Oxford:
Blackwell Science; 2004. p. 20-39 | |
dc.identifier | Tomaselli L. The microalgal cell. En: Richmond A, editor. Handbook of microalgal
culture: biotechnology and applied phycology, Oxford: Blackwell Science; 2004. p. 3-
19 | |
dc.identifier | Lombardi AT, Hidalgo MR, Vieira AAH. Copper complexing properties of dissolved
organic materials exuded by the freshwater microalgae Scenedesmus acuminatus
(Chlorophyceae). Chemosphere (2005); 60: 453-459 | |
dc.identifier | Becker EW. Biotechnology and exploitation of the green alga Scenedesmus obliquus
in India. Biomass (1984); 4: 1-19 | |
dc.identifier | Ördög V, Stirk WA, Lenobel R, Bancírová M, Strnad M, van Staden J, Szigeti J,
Németh L. Screening microalgae for some potentially useful agricultural and
pharmaceutical secondary metabolites. Journal of Applied Phycology (2004); 16 (4):
309-314 | |
dc.identifier | Roeselers G, van Loosdrecht MCM, Muyzer G. Phototrophic biofilms and their
potencial applications. Journal of Applied Phycology (2008); 20 (3): 227-235 | |
dc.identifier | Mandal S, Mallick N. Microalga Scenedesmus obliquus as a potential source for
biodiesel production. Applied Microbiology and Biotechnology (2009); 84 (2): 281-291 | |
dc.identifier | Burja AM, Banaigs B, Abou-Mansour E, Burgess JG, Wright PC. Marine cyanobacteria
– a profilic source of natural products. Tetrahedron (2001); 57: 9347-9377 | |
dc.identifier | Fogg GE. Algal cultures and phytoplankton ecology. Madison: University of Wisconsin
Press; 1966. | |
dc.identifier | Grobbelaar JU. Availability to algae of N and P adsorbed on suspended solids in turbid
waters of the Amazon River. Arch. Hydrobiol (1983); 96 (3): 302-316 | |
dc.identifier | Richmond A. Microalgal biotechnology at the turn of the millennium: a personal view.
Journal of Applied Phycology (2000); 12: 441-451 | |
dc.identifier | Grobbelaar JU. Carbon flow in the pelagic zone of a shallow turbid impoundment,
Wuras Dam. Arch. Hydrobiol (1985); 103 (1): 1-24 | |
dc.identifier | Grobbelaar JU. Algal nutrition: mineral nutrition. En: Richmond A, editor. Handbook of
microalgal culture: biotechnology and applied phycology, Oxford: Blackwell Science;
2004. p. 97-115 | |
dc.identifier | Richmond A. Biological principles of mass cultivation. En: Richmond A, editor.
Handbook of microalgal culture: biotechnology and applied phycology, Oxford:
Blackwell Science; 2004. p. 125-177 | |
dc.identifier | Tredici MR. Mass production of microalgae: photobioreactors. En: Richmond A, editor.
Handbook of microalgal culture: biotechnology and applied phycology, Oxford:
Blackwell Science; 2004. p. 178-214 | |
dc.identifier | Janssen M, Janssen M, de Winter M, Tramper J, Mur LR, Snel J, Wijffels RH.
Efficiency of light utilization of Chlamydomonas reinhardtii under medium-duration
light/dark cycles. Journal of Biotechnology (2000); 78: 123-137 | |
dc.identifier | Rosello Sastre R, Fleck-Schneider P, Posten C. Die function der polysaccharide der
mickroalge P. purpureum in ihrer produktionskinetik. Chemie Ingenieur Technik (2006);
78 (9): 1393. | |
dc.identifier | Yang Ch, Hua Q, Shimizu K. Energetics and carbon metabolismo during growth of
microalgal cells under photoautotrophic, mixotrophic and cyclic light-autotrophic/darkheterotrophic conditions. Biochemical Engineering Journal (2000); 6: 87-102 | |
dc.identifier | Sánchez JF, Fernández JM, Acién FG, Rueda A, Pérez-Parra J, Molina E. Influence of
culture conditions on the productivity and lutein content of the new strain
Scenedesmus almeriensis. Process Biochemistry (2008); 43: 398-405 | |
dc.identifier | Greque de Morais M, Viera Costa JA. Biofixation of carbon dioxide by Spirulina sp. and
Scenedesmus obliquus in a three-stage serial tubular photobioreactor. Journal of
Biotechnology (2007); 129: 439-445 | |
dc.identifier | Vunjak-Novanovik G, Kim Y, Wu X, Berzin I, Merchuk JC. Air-lift bioreactors for algal
growth on flue gas: mathematical modeling and pilot-plant studies. Ind. Eng. Chem.
Res. (2005); 44: 6154-6163 | |
dc.identifier | Lidén G. Understanding the bioreactor. Bioprocess and Biosystems Engineering
(2002); 24: 273-279 | |
dc.identifier | Muffler K, Ulber R. Downstream processing in marine biotechnology. Advances in
Biochemical Engineering/Biotechnology (2005); 97: 63-103 | |
dc.identifier | Gudin C, Therpenier C. Bioconversion of solar energy into organic chemicals by
microalgae. Adv Biotechnol Proc (1986); 6 (): 73-110 | |
dc.identifier | Wood AM, Everroad RC, Wingard LM. Measuring growth rates in microalgal cultures.
En: Robert A. Andersen, editor. Algal Culturing Techniques. USA: Academic Press;
2005. p. 269 – 285 | |
dc.identifier | STATGRAPHICS PLUS 5.0 [CD-ROM]. Copyright by statistical graphics coporation.
Estados Unidos. 2000. | |
dc.identifier | Box GEP, Hunter WG, Hunter JS. Statistics for experimenters: an introduction to
design, data analysis and model building. New York: John Wiley & Sons; 1978. (Series
in probability and mathematical statistics) | |
dc.identifier | Sharma SK, Mulvaney SJ, Rizvi SSH. Food processing engineering: theory and
laboratory experiments. New York: John Wiley & Sons; 1999. | |
dc.identifier | Pruvost J, Cornet J-F, Legrand J. Hydrodynamics influence on light conversion in
photobioreactors: an energetically consistent analysis. Chemical Engineering Science
(2008); 63 (14): 3679-3694 | |
dc.identifier | Mohn FH. Experiencies and strategies in the recovery of biomass from mass cultures
of microalgae. En: Sheler G. Soeder CJ, editors. Algae biomass. Amsterdam: Elsevier;
1980. p. 547–571. | |
dc.identifier | Molina Grima E, Belarbi E-H, Acién Fernández FG, Robles Medina A, Chisti Y.
Recovery of microalgal biomass and metabolites: process, options and economics.
Biotechnology Advances (2003); 20 (7-8): 491-515 | |
dc.identifier | Hansman E. Pigment analysis. En: Stain JR, editor. Hanbook of phycological methods,
culture metods, and growth measurements. Cambridge: Cambridge University Press,
1973. p. 359-368. | |
dc.identifier | Acién Fernández FG, García Camacho F, Sánchez Pérez JA, Fernández Sevilla JM,
Molina Grima E. Modeling of biomass productivity in tubular photobioreactors for
microalgal cultures: effects of dilution rate, tube diameter, and solar irradiance.
Biotechnology and Bioengineering (1998); 58 (6): 605-616 | |
dc.identifier | Meijer EA, Wijffels RH. Development of a fast, reproducible and effective method for
the extraction and quantification of proteins of micro-algae. Biotechnology Techniques
(1998); 12 (5): 353-358 | |
dc.identifier | Bradford MM. A rapid and sensitive method for the quantization of microgram
quantities of protein utilizing the principle of protein-dye binding. Anal Biochem (1976);
72: 248-254 | |
dc.identifier | Gordon S, Weber R. Colorimetric estimation of indole acetic acid. Plant Physiology
(1950); 26: 192-195 | |
dc.identifier | Yemm EW, Willis JA. The estimation of carbohydrates in plant extracts by anthrone.
Journal of Biochemistry (1954); 57 (3): 508-514 | |
dc.identifier | Band CJ. Efecto de la composición bioquímica de micralgas sobre el valor nutritivo de
dos cepas de Artemia. [Tesis de Maestría]. La Paz: Centro Interdisciplinario de
Ciencias Nacional, Instituto Politécnico Nacional; 1999. | |
dc.identifier | Lewin RA. Extracellular polysaccharides of green algae. Canadian Journal of
Microbiology (1956); 2: 665-672 | |
dc.identifier | Moore BG, Tischer RG. Extracellular polysaccharides of algae: effects on life-support
systems. Science (1964); 145 (3632): 586-587 | |
dc.identifier | Mazur H, Konop A, Synak R. Indole-3-acetic acid in the culture medium of two axenic
green microalgae. Journal of Applied Phycology (2001); 13 (1): 35-42 | |
dc.identifier | . Wazer JR Van, Lyons JW, Kim KY, Colewell RE. Viscosity and flow measurements: a
laboratory handbook of rheology. New York: John Wiley & Sons; 1963. | |
dc.identifier | Doran PM. Bioprocess Engineering Principles. London: Academic Press; 1995. | |
dc.identifier | Csögör Z, Herrenbauer M, Perner I, Schmidt K, Posten C. Design of a photo-bioreactor
for modeling purposes. Chemical Engineering and Processing (1999); 38: 517-523 | |
dc.identifier | Tredici MR. Bioreactors, Photo. En: Flickinger MC, Drew SW, editors. Encyclopedia of
Bioprocess Technology: Fermentation, Biocatalysis and Bioseparations. New York:
John Wiley & Sons; 1999 | |
dc.identifier | Acién Fernández FG, García Camacho F, Sánchez Pérez JA, Fernández Sevilla JM,
Molina Grima E. A model for light distribution and average solar irradiance inside
outdoor tubular photobioreactors for the microalgal mass culture. Biotechnology and
Bioengineering (1997); 55 (5): 701-714 | |
dc.identifier | Burguess G, Fernández-Velasco JG, Lovegrove K. Materials, geometry, and net
energy ratio of tubular photobioreactors for microalgal hydrogen production. En:
Memories of the 16th World Hydrogen Energy Congress. Lyon, France 13-16 June.
pp. 12. | |
dc.identifier | Qiang H, Faiman D, Richmond AE. Optimal tilt angles of enclosed reactors fro growing
photoautotrophic microorganisms outdoors. Journal of Fermentation and
Bioengineering (1998); 85 (2): 230-236 | |
dc.identifier | Osborne BA, Raven JA. Growth light level and photon absorption by cells of
Chlamydomonas rheinhardii, Dunaliella tertiolecta (Chlorophyceae, Volvocales),
Scenedesmus obliquus (Chlorophyceae, Chlorococcales) and Euglena viridis
(Euglenophyceae, Euglenales). European Journal of Phycology (1986); 21: 303-313 | |
dc.identifier | Molina Grima E, Fernández Sevilla JM, Sánchez Pérez JA, García Camacho F. A
study on simultaneous photolimitation and photoinhibition in dense microalgal cultures
taking into account incident and averaged irradiances. Journal of Biotechnology
(1996); 45: 59-69 | |
dc.identifier | Janssen M, Tramper J, Mur LR, Wijffels RH. Enclosed outdoor photobioreactors: light
regime, photosynthetic efficiency, scale-up, and future prospects. Biotechnology and
Bioengineering (2003); 81 (2): 193-210 | |
dc.identifier | Pirt SJ. The thermodynamic efficiency (quantum demand) and dynamics of
photosynthetic growth. The New Phytologist (1986); 102: 3-37 | |
dc.identifier | Bonardi V, Pesaresi P, Becker T, Wagner R, Pfannschmidt T, Jahns P, Leister D.
Photosystem II core phosphorylation and photosynthetic acclimation require two
different protein kinases. Nature Letters (2005); 437: 1179-1182 | |
dc.identifier | Renaud SM, Thinh L-V, Lambrinidis G, Parry DV. Effecto of temperatura on growth,
chemical composition and fatty acid composition of tropical Australian microalgae
grown in batch cultures. Aquaculture (2002); 211 (1-4): 195-214 | |
dc.identifier | Guil-Guerrero JL, Rebolloso-Fuentes MM. Nutrient composition of Chlorella spp. And
Monodus subterraneus cultured in a bubble column bioreactor. Food Biotechnology
(2008); 22 (): 218-233 | |
dc.identifier | Tarackhovskaya ER, Maslov YuI, Shishova MF. Phytohormones in algae. Russian
Journal of Plant Physiology (2007); 54 (2): 163-170 | |
dc.identifier | Ogbonna JC, Tanaka H. Light requirements and photosynthetic cell cultivation:
development of process for efficient light utilization in photobioreactors. Journal of
Applied Phycology (2000); 12: 207-218 | |
dc.identifier | Roselers, 2008. Hydrodynamics influence on light conversion in photobioreactors: an
energetically consistent analysis. Chemical Engineering Science (2008); 20: 3679-
3694 | |
dc.identifier | Singh S, Arad S, Richmond A. Extracellular polysaccharide production in outdoor
mass cultures of Porphyridium sp. in flat plate glass reactors. Journal of Applied
Phycology (2000); 12: 269-275 | |
dc.identifier | Lee Y-K, Pirt SJ. Energetics of photosynthetic algal growth: influence of intermittent
illumination in short (40 s) cycles. Journal of General Microbiology (1981); 124: 926-
935 | |
dc.identifier | Wu X, Merchuk JC. A model integrating fluid dynamics in the photosynthesis and
photoinhibition process. Chemical Engineering Science (2001); 56: 3527-3538 | |
dc.identifier | Merchuk JC, García-Camacho F, Molina-Grima E. Photobioreactor design and fluid
dynamics. Chemical and Biochemical Engineering (2007); 21 (4): 354-355 | |
dc.identifier | Märkl et al. 1991, Bronnenmeier, Wittek B. The resistance of microorganism to
hydrodynamic stress. Int Chem Eng (1991); 31: 185-197 | |
dc.identifier | Grobbelaar JU. Turbulence in mass algal cultures and the role of light/dark
fluctuations. Journal of Applied Phycology (1994); 6: 331-335 | |
dc.identifier | Dayananda C, Sarada R, Usha Rani M, Shamala TR, Ravishankar GA. Autotrophic
cultivation of Botryococcus braunii for the production of hydrocarbons and
exopolysaccharides in various media. Biomass and Bioenergy (2007); 31: 87-93 | |
dc.identifier | Rebolloso Fuentes MM, García Sánchez JL, Fernández Sevilla JM, Acién Fernández
FG, Sánchez Pérez JA, Molina Grima E. Outdoor continuous culture of Porphyridium
cruentum in a tubular photobioreactor: quantitative análisis of the daily cyclic variation
of culture parameters. Journal of Biotechnology (1999); 70 (): 271-288 | |
dc.identifier | Miller RL, Fredrickson AG, Brown AH, Tsuchiya HM. Hydromechanical method to
increase efficiency of algal photosynthesis. I&C Process Design and Development
(1964); 3 (2): 134-143 | |
dc.identifier | Bentley-Mowat JA. Do plant growth substances affect development and ecology of
unicellular algae? Wiss. Z. Univ. Rostock, math. Naturwiss (1967). Reihe 16: 445-449 | |
dc.identifier | Mazur H, Konop A, Synak R. Indole-3-acetic acid in the culture médium of two axenic
green microalgae. Journal of Applied Phycology (2001); 13: 35-42 | |
dc.identifier | http://hdl.handle.net/10818/7481 | |
dc.identifier | 127877 | |
dc.identifier | TE01340 | |
dc.description.abstract | A partir de la evaluación del crecimiento de las microalgas, Scenedesmus obliquus y Chlorella vulgaris, se estandarizaron las condiciones de producción y se seleccionó a Scenedesmus obliquus para la optimización e identificación de los parámetros de proceso relevantes en su producción. Aplicando un diseño factorial 23 por metodología de screening se evaluó el efecto e interacciones de tres variables de proceso, en la productividad y producción de exopolisacáridos (EPS) y fitohormonas en el sobrenadante (IAA, ácido indol acético). Las pruebas experimentales entregaron condiciones óptimas para las variables de respuesta consideradas con μ 0.64 d-1, EPS y IAA de 24.7 mg L-1 y 5.42 nM L-1 respectivamente, sobre un punto optimo ubicado en niveles máximos de las tres variables (11.000 lux, 4% mezcla CO2-aire, 1.200 rpm). | |
dc.language | spa | |
dc.publisher | Universidad de La Sabana | |
dc.publisher | Maestría en Diseño y Gestión de Procesos | |
dc.publisher | Facultad de Ingeniería | |
dc.rights | openAccess | |
dc.source | Universidad de La Sabana | |
dc.source | Intellectum Repositorio Universidad de La Sabana | |
dc.subject | Análisis de suelos | |
dc.subject | Cultivo de algas | |
dc.title | Obtención de los parámetros de proceso requeridos para el escalamiento de un bioproceso orientado al desarrollo de mejoradores de suelo a base de extractos de microalgas | |
dc.type | masterThesis | |