. "Planetary Science"@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . "Planetary physics: science and instrumentation"@en . . "3" . "Planetary science is now in its “Golden Age”. Dozens of spacecrafts developed and operated by ESA, NASA and other space agencies have delivered a wealth of valuable data about Solar System planets and exoplanets. Data analysis, theoretical studies and numerical modelling, aiming at understanding of the conditions and processes on the planets in the Solar System and beyond, especially those relevant to habitability, are in high demand. Future more sophisticated and challenging planetary missions are being planned and developed by space agencies.\n\nThis course will provide an overview of the methods and instrumentation currently used in planetary research supported by representative examples from recent Solar System missions. The course will deliver a broad picture of conditions and processes on the Solar System planets in their complexity and diversity. The students will also get a preliminary understanding of how concepts of planetary missions payload are designed, including setting up science objectives and requirements, defining priorities and complementarities. The course will provide a “bridge” to exoplanet investigations where appropriate.\n\nThe detailed outline of the course is:\n\nRemote sensing methods and instrumentation\nMethods and instruments for in-situ investigations\nGrand Tour of planetary surfaces\nGrand Tour of planetary atmospheres\nScience payload concepts: from objectives to requirements\n\nOutcome:\nUpon completion of this course, students will be able to:\n\nUnderstand the areas of applicability of various remote sensing and in-situ methods in planetary physics, their main features, advantages, limitations and main results\nAcquire a broad picture of main features and conditions on the planets in the Solar System\nDiscuss and explain major open questions in the planetary physics\nUnderstand and discuss the logics and the way science payload concepts for ESA planetary missions are being designed\nDiscuss and follow current literature in the field of planetary physics" . . "Presential"@en . "FALSE" . . "Master of Astronomy and Data Science"@en . . "https://www.universiteitleiden.nl/en/education/study-programmes/master/astronomy/astronomy-and-data-science" . "120"^^ . "Presential"@en . "In the master’s specialisation Astronomy and Data Science you focus on development and application of new data-mining technologies, fully embracing modern astronomy as a data rich science. You combine the research curriculum in Astronomy with in-depth training in Computer Science.\n\nThe Astronomy and Data Science master’s programme is built on world-class computational astrophysics research as well as hightech industry expertise. It covers a wide range of research areas studying complex astronomical phenomena, including radiative transfer, computation of dynamical internal galaxy structures and hydrodynamical modeling of galaxy formation and evolution of the intergalactic medium.\n\nThis two-year Astronomy and Data Sicence programme uniquely combines advanced Astronomy courses of the Leiden Observatory and relevant courses from the Computer Science master’s programme of the Leiden Institute of Advanced Computer Science including advanced data mining and neural networks. To this end, the Leiden Observatory offers sophisticated computational facilities ranging from local computer clusters to high-performance systems at national and international computing centers.\n\nOutcome:\nDuring the programme, you learn to perform academically sound research and evaluate scientific information independently and critically. Without exception, you actively participate in current research within the institute and are individually supervised by our international scientific staff. Students with a Leiden degree in Astronomy become strong communicators and collaborators and can easily operate in an international setting. You will acquire extensive astronomical research experience and highly advanced analytical and problem solving skills."@en . . . . . . "2"@en . "FALSE" . . "Master"@en . "Thesis" . "2314.00" . "Euro"@en . "19600.00" . "Mandatory" . "Most graduates holding a MSc degree in Astronomy from Leiden University find work in many different capacities, including:\n\n1. Research: universities, observatories, research institutes\n2. Industry and consultancy: ICT, R&D, telecom, high technology, aerospace\n3. Finance: banking, insurance, pension funds\n4. Public sector: governments, policy makers, high schools\n5. Science communication: journalism, popular writing, museums\n6. Typical jobs for Astronomy graduates include:\n\nScientific researcher (postdoc, research fellow, professor)\n1. R&D engineer\n2. Consultant\n3. Data scientist, statistician\n4. Policy advisor, public information officer (e.g. Ministry of Foreign Affairs)\n5. High school physics teacher\n6. Scientific editor for magazines, newspapers and other media\n7. Research at Leiden Observatory\n\nIf you want to get more deeply involved in research after graduating in Astronomy, consider pursuing a PhD at Leiden Observatory. If you have completed the Leiden master’s degree programme in Astronomy, you are directly eligible for admission to our PhD programme"@en . "no data" . "TRUE" . "Upstream"@en . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .