01117nam a2200289 i 450099100129837970753620020507114038.0951201s1965 us ||| | eng b10201117-39ule_instLE00645452ExLDip.to Fisicaita510(022:076)510.35510.44Spiegel, Murray R.1929Theory and problems of Laplace transforms :including 450 solved problems /by Murray R. SpiegelNew York :McGraw-Hill Book Co.,c1965261 p. ;27 cm.Schaum's outline seriesLaplace transformations.b1020111717-02-1727-06-02991001298379707536LE006 510(022+076) SCH12006000010689le006-E0.00-l- 01010.i1024875427-06-02LE006 510(022+076) SCH1LE006-79le006nE0.00-lm 00000.i1024876627-06-02Theory and problems of Laplace transforms190983UNISALENTOle00601-01-95ma -engus 0203445oam 2200577 450 991068823650332120230621141346.09782889198122 (ebook)(CKB)3710000000631095(oapen)https://directory.doabooks.org/handle/20.500.12854/44471(EXLCZ)99371000000063109520191103c2016uuuu uu |engurmn|---annantxtrdacontentcrdamediacrrdacarrierCyanobacteria the green E. coli /edited by Anne M. Ruffing and Toivo KallasFrontiers Media SA2016Switzerland :Frontiers Media SA,20161 online resource (114 pages) illustrations, chartsFrontiers Research TopicsIncludes bibliographical references.As the world struggles to reduce its dependence on fossil fuels and curb greenhouse gas emissions, industrial biotechnology is also ‘going green.’ Escherichia coli has long been used as a model Gram-negative bacterium, not only for fundamental research, but also for industrial applications. Recently, however, cyanobacteria have emerged as candidate chassis for the production of commodity fuels and chemicals, utilizing CO2 and sunlight as the main nutrient requirements. In addition to their potential for reducing greenhouse gas emissions and lowering production costs, cyanobacteria have naturally efficient pathways for the production metabolites such as carotenoids, which are of importance in the nutraceutical industry. The unique metabolic and regulatory pathways present in cyanobacteria present new challenges for metabolic engineers and synthetic biologists. Moreover, their requirement for light and the dynamic regulatory mechanisms of the diurnal cycle further complicate the development and application of cyanobacteria for industrial applications. Consequently, significant advancements in cyanobacterial engineering and strain development are necessary for the development of a ‘green E. coli’. This Research Topic will focus on cyanobacteria as organisms of emerging industrial relevance, including research focused on the development of genetic tools for cyanobacteria, the investigation of new cyanobacterial strains, the construction of novel cyanobacterial strains via genetic engineering, the application of ‘omics’ tools to advance the understanding of engineered cyanobacteria, and the development of computational models for cyanobacterial strain development.CyanobacteriaCarbon captureSustainable bioproducts BiofuelsGreen chemistrygreen E. coliengineered cyanobacteriaCell factoriesGreen chemicalsCarbon CaptureCyanobacteriagenetically modified cyanobacteriasustainable bioproductsPhotosynthesisBiofuelsCyanobacteria.Carbon capture.Sustainable bioproducts .Biofuels.Green chemistry.Anne M. Ruffingauth1351595Ruffing Anne M.Kallas ToivoUkMaJRU9910688236503321Cyanobacteria3122464UNINA