. "Materials Chemistry"@en . . . . . . . . . . . . . . . "Spectroscopy techniques"@en . . "6" . "Specific Competition\nCE1 - Understand the basic conceptual schemes of Astrophysics\nCE2 - Understand the structure and evolution of stars\nCE7 - Know how to find solutions to specific astrophysical problems by themselves using specific bibliography with minimal supervision. Know how to function independently in a novel research project\nCE10 - Use current scientific instrumentation (both Earth-based and Space-based) and learn about its innovative technologies.\nGeneral Competencies\nCG1 - Know the advanced mathematical and numerical techniques that allow the application of Physics and Astrophysics to the solution of complex problems using simple models\nCG2 - Understand the technologies associated with observation in Astrophysics and instrumentation design\nBasic skills\nCB6 - Possess and understand knowledge that provides a basis or opportunity to be original in the development and/or application of ideas, often in a research context\nCB7 - That students know how to apply the knowledge acquired and their ability to solve problems in new or little-known environments within broader contexts\nCB8 - That students are able to integrate knowledge and face the complexity of formulating judgments based on information that, being incomplete or limited, includes reflections on the social and ethical responsibilities linked to the application of their knowledge and judgments\nCB10 - That students possess the learning skills that allow them to continue studying in a way that will be largely self-directed or autonomous\nExclusive to the Specialty in Observation and Instrumentation\nCX7 - Apply the different techniques that allow us to obtain physical information about the Universe from the spectrum\n6. Subject contents\nTheoretical and practical contents of the subject\n- Topics:\n\n1. Introduction to instrumentation and observation techniques in optical spectroscopy.\n Processing of optical astronomical spectra with CCD detectors (the IRAF astronomical data reduction package and Python are used).\n Visual extragalactic spectroscopy practice. Correction of instrumental effects. Wavelength and flow calibration. Spectra extraction.\n Spectrum analysis: line adjustments, determination of speeds, equivalent widths, flows and intensities.\n\n2. Introduction to spectroscopy techniques in the infrared (IR) range.\n Practice of extragalactic spectroscopy in the IR (the IRAF astronomical data reduction package is used).\n Correction of instrumental effects. Calibration, extraction and analysis of spectra.\n\n3. Introduction to spectropolarimetry techniques. \n Solar spectropolarimetry practice. Inference of the magnetic field in the solar atmosphere by means of the spectroscopic traces in the Stokes parameters. Measurement of the thermodynamic properties of the solar surface." . . "Presential"@en . "FALSE" . . "Master in Astrophysics"@en . . "https://www.ull.es/en/masters/astrophysics/" . "90"^^ . "Presential"@en . "The exceptional atmospheric conditions for top-quality astronomic observation to be found in the Canary Islands, together with its geographic proximity and excellent connections with Europe, justify the presence here of the European Northern Hemisphere Observatory (ENO). This fact, along with the consequent concentration of teachers and researchers around the Canary Island Institute of Astrophysics, the ULL Department of Astrophysics and the Observatories, generates the ideal atmosphere for a Master in Astrophysics in which direct contact with leading professionals represents exceptional value added. The Master has been designed based on an ample and rigorous choice of subjects, options and itineraries that that take the form of three specialities: “Theory and Computing Speciality”, “Observation and Instrumentation Speciality” and “Material Structure”\n\nGeneral skills\nKnow the advanced mathematical and numerical techniques that allow Physics and Astrophysics to be applied to solving complex problems using simple models\nUnderstand the technologies associated with observation in Astrophysics and the design of instrumentation\nAnalyse a problem, study the possible solutions published and propose new solutions or lines of attack\nAssess orders of magnitude and develop a clear perception of physically different situations that show analogies allowing the use of synergies and known solutions for new problems\nSpecific skills\nUnderstand the basic conceptual schemes of Astrophysics\nUnderstand the structure and evolution of the stars\nUnderstand the mechanisms of nucleosynthesis\nUnderstand the structure and evolution of galaxies\nUnderstand the models of the origin and evolution of the Universe\nUnderstand the structure of matter to be able to solve problems related to the interaction between matter and radiation in different energy ranges\nKnow how to find solutions to specific astrophysical problems on your own, using specific bibliography with minimum supervision\nKnow how to work independently on new research projects\nKnow how to programme, at least in one important language for scientific calculation in Astrophysics\nUnderstand the instrumentation used to observe the universe in the different frequency ranges\nUse current scientific instrumentation (both Earth-based and Space-based) and have a command of their innovative technologies\nKnow how to use current astrophysical instrumentation (both in terrestrial and space observatories), especially the instrumentation that uses the most innovative technology and know the foundations of the technology used\nApply the knowledge acquired to undertake an original research work in Astrophysics"@en . . . "1.5"@en . "FALSE" . . . "Master"@en . "Thesis" . "Not informative" . "no data"@en . "Not informative" . "None" . "no data"@en . "no data" . "FALSE" . "Upstream"@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .