TY - JOUR A1 - Zimmermann, Matthias A1 - Horn-Conrad, Antje A1 - Scholz, Jana A1 - Elsner, Birgit A1 - Schubarth, Wilfried A1 - Engel, Silke A1 - Blaum, Niels A1 - Rößling, Claudia A1 - Mikulla, Stefanie T1 - Portal - Spezial 2020: Corona BT - Das Potsdamer Universitätsmagazin N2 - Corona. Schon mal gehört? Noch Weihnachten 2019 hätten viele ahnungslos geantwortet: „Nö.“ Besser Informierte hätten zurückgefragt: „Meinst du die Korona – den Hof um die Sonne?“ Und ganz Schlaue hätten gesagt: „Klar, trink ich gern.“ Doch spätestens seit Februar beherrscht das Virus die Nachrichten, seit März auch unser Leben. Nach und nach mussten wir alle lernen, uns (wieder) richtig die Hände zu waschen und die „Niesetikette“ zu befolgen, Abstand zu halten, zu Hause zu arbeiten oder zu lernen, Masken zu tragen oder gar zu nähen – und überhaupt: uns mit dem Ausnahmezustand, der zum Dauerzustand zu werden droht, zu arrangieren. Aber wie macht das eine ganze Universität – mit 21.000 Studierenden, mehr als 4.500 Beschäftigten, Tausenden Kursen, Praktika, Prüfungen und Forschungsprojekten? Wie hält man einen Tanker an – in voller Fahrt – und rüstet ihn um für einen pandemiesicheren Betrieb? Die zurückliegenden Wochen haben gezeigt: Es geht. Inzwischen läuft mit dem Sommersemester 2020 das erste Online-Semester der Hochschulgeschichte. Auch das hätte Ende 2019 niemand für möglich gehalten, schon gar nicht so bald. Das Referat für Presse- und Öffentlichkeitsarbeit musste wie alle Unibereiche lernen, mit den ungewöhnlichen Umständen umzugehen, die mal bedrohlich, mal lästig, mal ermüdend und mal eben einfach nur umständlich wirkten. Wir haben uns bemüht, so gut es ging, zu informieren – darüber was sich tat, was getan werden musste und konnte. Und was kommt. Doch wir wollten noch mehr wissen: Was sagen die Potsdamer Wissenschaftlerinnen und Wissenschaftler zur Corona- Pandemie, ihren Auswirkungen und Folgen, aber auch dazu, was sich dagegen tun lässt? Wie genau funktioniert eine Universität unter den besonderen Umständen? Wie wird gearbeitet, studiert, geforscht? Wie verlagert man ein ganzes Semester in den Online-Betrieb? Auf der Suche nach Antworten auf diese und viele weitere Fragen ist eine Vielzahl von Texten entstanden, die wir nach und nach auf der Webseite der UP veröffentlicht haben als „Beiträge aus der Universität Potsdam zur Corona-Pandemie“.* Eine gekürzte Auswahl dieser Texte haben wir für diese „Portal Spezial“ zusammengestellt. Nicht, weil wir über nichts anderes als den Corona-Virus mehr reden wollen, sondern weil wir dokumentieren wollen, dass die Universität Potsdam durch die Pandemie keineswegs in einen Dornröschenschlaf versetzt wurde. Vielmehr entstanden durch das Engagement vieler Forschender, Studierender und Beschäftigter zahlreiche Initiativen, Ideen, Projekte, Strukturen und Neuerungen, die zeigen: Die Universität Potsdam lässt sich nicht unterkriegen! Deshalb hoffen wir, dass die Lektüre des Heftes Ihnen trotz der weiterhin herausfordernden Umstände Freude und Mut macht. (Die Texte entstanden alle im März/April 2020, als viele Entwicklungen noch am Anfang standen und ihr Verlauf nicht absehbar war. Wir haben sie dennoch unverändert aufgenommen, um diese Phase und die Reaktion der Wissenschaft darauf zu dokumentieren.) T3 - Portal: Das Potsdamer Universitätsmagazin - Spezial 2020 Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-481430 SN - 1618-6893 IS - Spezial 2020 ER - TY - JOUR A1 - Zimmermann, Matthias A1 - Wilke, Monika A1 - Horn-Conrad, Antje A1 - Kampe, Heike A1 - Scholz, Jana ED - Engel, Silke ED - Zimmermann, Matthias T1 - Portal Wissen = Energy BT - The Research Magazine of the University of Potsdam N2 - Energy – there is something to it. There is, of course, the matter-of-fact definition in every student encyclopedia: “the capacity to do mechanical work, transfer heat, or emit light.” In this way, energy accompanies us, often undetected, all day long: getting out of bed, turning on the heat, switching on the lights, taking a hot shower, getting dressed, making coffee, having breakfast – before we have even left the house, we have already released, transformed, applied, and refueled a lot of energy. And we haven’t even worked, at least not in the traditional sense. But energy is not just a physical quantity that, due to its omnipresence, plays a key role in every natural science discipline, such as biology and chemistry, but also in almost every technical field. It is also indispensable when it comes to how we understand and describe our world and our activities – and it has been for a long time. How about an example? The Greek philosopher Aristotle was the first to speak of enérgeia, for him a rather nonphysical thing, a living “reality and effectiveness ” – that which makes the possible real. About 2,100 years later, the uncrowned king of German literature Johann Wolfgang von Goethe declared it to be a humanistic essence. “What can we call our own if not energy, strength, and will!” And for his contemporary Wilhelm von Humboldt, energy “was the human’s first and only virtue”. Although physics began to dominate the concept of energy when it became the leading science in the 19th century, energy remained significant in many areas. Reason enough for us to take a look at energy-related matters at the University of Potsdam. We found them in a wide range of disciplines: While Iranian physicist Safa Shoaee is researching how organic materials can be used to manufacture the solar cells of the future, Swedish environmental researcher Johan Lilliestam is focusing on the different dimensions of the energy transition to learn what makes it successful. Slavicist Susanne Strätling, on the other hand, crosses the boundaries of her discipline as she examines a complex conceptual history and tries to find out why energy electrifies us today more than ever. And physicist Markus Gühr is able to use ultrashort flashes of light to investigate how molecules change under its influence and convert energy in the process. Of course, we have enough energy to highlight the diversity of research at the University of Potsdam besides the feature topic of this issue. A cognitive researcher, for example, explains why our brain processes both music and language according to its own respective rhythm, while an environmental researcher presents a method that uses particles from outer space to measure soil moisture. Educational researchers have also launched a study on hate speech in schools and we introduce a palaeoclimatologist who is one of twelve researchers in the new postdoc program at the University of Potsdam. We have spared no energy! T3 - Portal Wissen: The research magazine of the University of Potsdam [Englische Ausgabe] - 01/2020 Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-472978 SN - 2198-9974 ER - TY - JOUR A1 - Kampe, Heike A1 - Zimmermann, Matthias A1 - Horn-Conrad, Antje A1 - Scholz, Jana A1 - Pchalek, Magda A1 - Szameitat, Ulrike A1 - Engel, Silke A1 - Eckardt, Barbara T1 - Portal = Bioökonomie BT - Das Potsdamer Universitätsmagazin N2 - Ein bisschen sperrig ist es schon, dieses Wort: Bioökonomie. Noch ist es vielleicht nicht in aller Munde, aber das könnte sich dieses Jahr ändern. Immerhin ist es das Thema des Wissenschaftsjahres 2020. Und selbst wenn „Bioökonomie“ dem einen oder anderen schwer über die Lippen geht – sie umgibt uns bereits. Das lässt sich auch an den zahlreichen Projekten erkennen, die sich an der Universität Potsdam mit der nachhaltigen Nutzung nachwachsender Ressourcen beschäftigen. In dieser Ausgabe des Unimagazins Portal stellen wir Ihnen Menschen vor, die Bausteine erarbeiten für eine moderne, biobasierte Wirtschaft, die biologische Materialien, Pflanzen, Tiere und Mikroorganismen umweltschonend und effizient nutzt. Eine brandenburgische Initiative zum Beispiel bringt Landwirte und Lehrer, Vertreter aus Verwaltung, Einzelhandel oder Umweltorganisationen zur bioökonomischen Wende ins Gespräch. Eine Informatikerin und eine Agrarwissenschaftlerin erklären, was die Digitalisierung in der Landwirtschaft leisten kann, und wir erfahren, wie die Universität weiter Treibhausgase einsparen wird. Ernährungswissenschaftler kultivieren Algen und Salzpflanzen, um unseren Gaumen an veränderte (land-)wirtschaftliche Bedingungen zu gewöhnen. Ob schon Alexander von Humboldt die Welt durch die Bioökonomie- Brille gesehen hat? Wie entwickeln Chemiker abbaubare Polymere? Und wie können Heilpflanzen Tropenkrankheiten bekämpfen? All dies in unserer Titelgeschichte. Wie immer haben wir uns auch auf dem Campus umgesehen und und dabei interessante Geschichten aufgespürt. Wie studiert es sich eigentlich mit Mitte 60 – und wie ist es, als Schüler Uni-Luft zu schnuppern? Sie erfahren, wer außer Studierenden und Beschäftigten noch in den Hallen des Hochschulsports boxt und warum es so wichtig ist, sich für die Belange ausländischer Studierender einzusetzen. Botaniker zeigen uns die Flora Sansibars und zwei junge Gärtner nehmen uns mit in die Potsdamer Pflanzenwelt; wir erfahren, warum botanisches Wissen gar nicht altmodisch ist und Ernten auch Studierenden Spaß macht. Ein Spitzensportler mit Aussichten auf Olympia erklärt, warum fünf Sportarten besser sind als eine. Wir haben uns über die Gender Studies informiert und über neue Lernroboter an Schulen. Lesen Sie, wie die Universitätsschule aussehen kann und ob der Amerikanische Traum wahr geworden ist! Ob Vitamin C in der Krebstherapie eingesetzt werden könnte, warum sich ein Besuch in deutschen Geoparks lohnt und wie sich Rechtsextremismus in Deutschland entwickelt – wir haben uns schlau gemacht. 15 unverblümte Fragen hat uns ein Ernährungswissenschaftler beantwortet. Und wir wollten noch mehr wissen: Wie das Wetter eigentlich bei Shakespeare ist, warum das Lehramt der tollste Beruf der Welt ist, wie die Potsdamer Konferenz die Welt veränderte und welche optischen Schätze sich im Fotoarchiv der Uni Potsdam verbergen. Zuletzt erfreuen Sie sich doch an einigen verbalen Schätzen, die hier und da an der Universität gehoben werden. T3 - Portal: Das Potsdamer Universitätsmagazin - 1/2020 Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-468105 SN - 1618-6893 IS - 1/2020 ER - TY - JOUR A1 - Mangelsdorf, Birgit A1 - Horn-Conrad, Antje A1 - Bagdahn, Christian A1 - Schmidt, Bernd A1 - Eckardt, Barbara A1 - Görlich, Petra A1 - Peter, Andreas A1 - Pösl, Thomas A1 - Nestler, Ralf A1 - Zimmermann, Matthias T1 - Portal = Wenn die Chemie stimmt: Lösungen für heute und morgen T2 - Das Potsdamer Universitätsmagazin N2 - Aus dem Inhalt: - Wenn die Chemie stimmt: Lösungen für heute und morgen - Das Kreuz mit dem Kreuz - „Das verrückteste Jahr unseres Lebens“ T3 - Portal: Das Potsdamer Universitätsmagazin - 03/2011 Y1 - 2011 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-459810 SN - 1618-6893 IS - 03/2011 ER - TY - JOUR A1 - Cornel, Hajo A1 - Trilcke, Peer A1 - Winkler, Kurt A1 - Zimmermann, Matthias A1 - Horn-Conrad, Antje A1 - Engel, Silke A1 - Szameitat, Ulrike A1 - Krafzik, Carolin A1 - Kampe, Heike A1 - Görlich, Petra A1 - Eckardt, Barbara A1 - Eccard, Jana T1 - Portal = Theodor Fontane: Zum 200. Geburtstag BT - Das Potsdamer Universitätsmagazin N2 - Aus dem Inhalt: - Theodor Fontane: Zum 200. Geburtstag - Licht an! - Durch Nacht und Eis T3 - Portal: Das Potsdamer Universitätsmagazin - 01/2019 Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-443528 SN - 1618-6893 IS - 01/2019 ER - TY - JOUR A1 - Schmidt, Anna A1 - Eckardt, Barbara A1 - Marszałek, Magdalena A1 - Görlich, Petra A1 - Bieber, Sabine A1 - Kampe, Heike A1 - Jäger, Sophie A1 - Horn-Conrad, Antje A1 - Günther, Oliver A1 - Seckler, Robert A1 - Seppä, Silvana A1 - Guske, Katja A1 - Szameitat, Ulrike A1 - Bezzenberger, Tilman A1 - Sütterlin, Sabine A1 - Weller, Nina A1 - Klauke, Lars T1 - Portal = Sommer an der Uni: Leere Hörsäle? Volle Terminkalender! BT - Das Potsdamer Universitätsmagazin N2 - Aus dem Inhalt: - Sommer an der Uni: Leere Hörsäle? Volle Terminkalender! - Stärken stärken - Unter Stress T3 - Portal: Das Potsdamer Universitätsmagazin - 03/2014 Y1 - 2014 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-443021 IS - 03/2014 ER - TY - JOUR A1 - Günther, Oliver A1 - Weller, Nina A1 - Jäger, Sophie A1 - Grabsch, Gabriele A1 - Eckardt, Barbara A1 - Sütterlin, Sabine A1 - Kampe, Heike A1 - Szameitat, Ulrike A1 - Lange, Ruth A1 - Zimmermann, Matthias A1 - Horn-Conrad, Antje T1 - Portal = Investition in die Zukunft: Forschung für die digitale Gesellschaft BT - Das Potsdamer Universitätsmagazin N2 - Aus dem Inhalt: - Investition in die Zukunft: Forschung für die digitale Gesellschaft - Doppelt stark - Eine für alles T3 - Portal: Das Potsdamer Universitätsmagazin - 01/2014 Y1 - 2014 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-442712 SN - 1618-6893 IS - 01/2014 ER - TY - JOUR A1 - Kampe, Heike A1 - Horn-Conrad, Antje A1 - Zimmermann, Matthias A1 - Scholz, Jana A1 - Görlich, Petra A1 - Eckardt, Barbara A1 - Krafzik, Carolin ED - Engel, Silke ED - Zimmermann, Matthias T1 - Portal Wissen = Data BT - The Research Magazine of the University of Potsdam N2 - Data assimilation? Stop! Don’t be afraid, please, come closer! No tongue twister, no rocket science. Or is it? Let’s see. It is a matter of fact, however, that data assimilation has been around for a long time and (almost) everywhere. But only in the age of supercomputers has it assumed amazing proportions. Everyone knows data. Assimilation, however, is a difficult term for something that happens around us all the time: adaptation. Nature in particular has demonstrated to us for millions of years how evolutionary adaptation works. From unicellular organisms to primates, from algae to sequoias, from dinosaurs ... Anyone who cannot adapt will quickly not fit in anymore. We of course have also learned to adapt in new situations and act accordingly. When we want to cross the street, we have a plan of how to do this: go to the curb, look left and right, and only cross the street if there’s no car (coming). If we do all this and adapt our plan to the traffic we see, we will not just safely cross the street, but we will also have successfully practiced data assimilation. Of course, that sounds different when researchers try to explain how data assimilation helps them. Meteorologists, for example, have been working with data assimilation for years. The German Weather Service writes, “In numerical weather prediction, data assimilation is the approximation of a model run to the actual development of the atmosphere as described by existing observations.” What it means is that a weather forecast is only accurate if the model which is used for its calculation is repeatedly updated, i.e. assimilated, with new measurement data. In 2017 an entire Collaborative Research Center was established at the University of Potsdam, CRC 1294, to deal with the mathematical basics of data assimilation. For Portal Wissen, we asked the mathematicians and speakers of the CRC Prof. Sebastian Reich and Prof. Wilhelm Huisinga how exactly data assimilation works and in which areas of research they can be used profitably in the future. We have looked at two projects at the CRC itself: the analysis of eye movements and the research on space weather. In addition, the current issue is full of research projects that revolve around data in very different ways. Atmospheric physicist Markus Rex throws a glance at the spectacular MOSAiC expedition. Starting in September 2019, the German research icebreaker “Polarstern” will drift through the Arctic Ocean for a year and collect numerous data on ice, ocean, biosphere, and atmosphere. In the project “TraceAge”, nutritionists will use the data from thousands of subjects who participated in a long-term study to find out more about the function of trace elements in our body. Computer scientists have developed a method to filter relevant information from the flood of data on the worldwide web so as to enable visually impaired to surf the Internet more easily. And a geophysicist is working on developing an early warning system for volcanic eruptions from seemingly inconspicuous seismic data. Not least, this issue deals with the fascination of fire and ice, the possibilities that digitization offers for administration, and the question of how to inspire children for sports and exercise. We hope you enjoy reading – and if you send us some of your reading experience, we will assimilate it into our next issue. Promised! T3 - Portal Wissen: The research magazine of the University of Potsdam [Englische Ausgabe] - 02/2019 Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-442574 SN - 2198-9974 IS - 02/2019 ER - TY - JOUR A1 - Zimmermann, Matthias A1 - Horn-Conrad, Antje A1 - Kampe, Heike A1 - Scholz, Jana A1 - Engel, Silke A1 - Eckardt, Barbara A1 - Krafzik, Carolin A1 - Schneider, Simon A1 - Schumacher, Juliane T1 - Portal Wissen = Energie BT - Das Forschungsmagazin der Universität Potsdam N2 - Energie hat etwas. Natürlich – so die nüchterne Definition in jedem Schülerlexikon – „die Fähigkeit, mechanische Arbeit zu verrichten, Wärme abzugeben oder Licht auszustrahlen“. Auf diese Weise begleitet sie uns, oft unerkannt, den lieben langen Tag: Aus dem Bett wuchten, die Heizung aufdrehen, das Licht anmachen, heiß duschen, anziehen, Kaffee kochen, frühstücken – noch bevor wir das Haus verlassen, haben wir reichlich Energie freigesetzt, umgewandelt, zugeführt und getankt. Und dabei haben wir noch nicht einmal selbst gearbeitet, jedenfalls im herkömmlichen Sinn. Aber Energie ist nicht nur eine physikalische Größe, die aufgrund ihrer Allgegenwart in jeder naturwissenschaftlichen Disziplin – wie Biologie und Chemie, aber auch so ziemlich alle technischen Felder – eine zentrale Rolle spielt. Vielmehr ist sie ebenso nicht wegzudenken, wenn es darum geht, wie wir unsere Welt und unser Wirken in ihr verstehen und beschreiben. Und zwar nicht erst seit heute. Eine Kostprobe gefällig? Der griechische Philosoph Aristoteles war der Erste, der von enérgeia sprach, für ihn eher unphysikalisch eine lebendige „Wirklichkeit und Wirksamkeit“ – das, was das Mögliche real werden lässt. Rund 2100 Jahre später erklärte sie der ungekrönte König der deutschen Literatur Johann Wolfgang von Goethe zum humanistischen Wesenskern: „Was können wir denn unser Eigenes nennen als die Energie, die Kraft, das Wollen!“ Und für seinen Zeitgenossen Wilhelm von Humboldt war „Energie die erste und einzige Tugend des Menschen“. Auch wenn die Physik mit ihrem Aufstieg zur Leitwissenschaft im 19. Jahrhundert auch den Energiebegriff zu dominieren begann, blieb dieser doch in vielen Gebieten zu Hause. Grund genug für uns, einmal zu schauen, wo es an der Universität Potsdam energetisch zugeht. Wir wurden in verschiedensten Disziplinen fündig: Während die iranische Physikerin Safa Shoaee erforscht, wie sich mit organischen Materialien die Solarzellen der Zukunft herstellen lassen, nimmt der schwedische Umweltwissenschaftler Johan Lilliestam die verschiedenen Dimensionen der Energiewende in den Fokus, um zu klären, wovon ihr Gelingen abhängt. Die Slavistin Susanne Strätling wiederum lässt auf der Suche nach einer komplexen Begriffsgeschichte sämtliche Disziplingrenzen hinter sich und versucht zu ergründen, warum die Energie uns heute mehr denn je elektrisiert. Und dem Physiker Markus Gühr gelingt es, mithilfe von ultrakurzen Lichtblitzen zu untersuchen, wie sich Moleküle unter Lichteinfluss verändern und dabei Energie umwandeln. Freilich haben wir genug Energie, um neben dem Titelthema auch Einblicke in die Vielfalt der Forschung an der Universität Potsdam zusammenzutragen. So erklärt ein Kognitionswissenschaftler, warum unser Hirn Musik und Sprache gleichermaßen nach ihrem Rhythmus verarbeitet, und ein Materialforscher zeigt, wie Bakterien künftig unter richtiger Anleitung biologisch abbaubares Plastik produzieren. Sozialwissenschaftler untersuchen, ob es der Bundeswehr gelingt, echte Gleichstellung für wirklich alle zu schaffen, während Umweltwissenschaftler eine Methode entwickeln, bei der sich mithilfe von Teilchen aus dem All die Bodenfeuchte messen lässt. Ein Psychologe erforscht den Zusammenhang zwischen Emotionen und Gedächtnis und Bildungswissenschaftler bringen eine Studie zu Hate Speech in Schulen auf den Weg. Außerdem stellen wir mit einer Paläoklimatologin und einer Astrophysikerin zwei der insgesamt zwölf Forschenden des neuen Postdoc-Programms der Universität Potsdam vor. Gin ohne Akohol, Sprachforschung mit Ultraschall, Drohnen im Einsatz der Wissenschaft, Rechtswissenschaft im Dienste der Menschenrechte und vieles mehr finden sich in dieser Ausgabe. Wir haben keine Energien gescheut! T3 - Portal Wissen: Das Forschungsmagazin der Universität Potsdam [Deutsche Ausgabe] - 01/2020 Y1 - 2020 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-442521 SN - 2194-4237 IS - 01/2020 ER - TY - JOUR A1 - Zimmermann, Matthias A1 - Horn-Conrad, Antje A1 - Görlich, Petra A1 - Schlegel, Karoline A1 - Kampe, Heike ED - Engel, Silke ED - Zimmermann, Matthias T1 - Portal Wissen = Artificial intelligence BT - The Research Magazine of the University of Potsdam N2 - For a long time, there were things on this planet that only humans could do, but this time might be coming to an end. By using the universal tool that makes us unique – our intelligence – we have worked to eliminate our uniqueness, at least when it comes to solving cognitive tasks. Artificial intelligence is now able to play chess, understand language, and drive a car – and often better than we. How did we get here? The philosopher Aristotle formulated the first “laws of thought” in his syllogisms, and the mathematicians Blaise Pascal and Wilhelm Leibniz built some of the earliest calculating machines. The mathematician George Boole was the first to introduce a formal language to represent logic. The natural scientist Alan Turing created his deciphering machine “Colossus,” the first programmable computer. Philosophers, mathematicians, psychologists, and linguists – for centuries, scientists have been developing formulas, machines, and theories that were supposed to enable us to reproduce and possibly even enhance our most valuable ability. But what exactly is “artificial intelligence”? Even the name calls for comparison. Is artificial intelligence like human intelligence? Alan Turing came up with a test in 1950 to provide a satisfying operational definition of intelligence: According to him, a machine is intelligent if its thinking abilities equal those of humans. It has to reach human levels for any cognitive task. The machine has to prove this by convincing a human interrogator that it is human. Not an easy task: After all, it has to process natural language, store knowledge, draw conclusions, and learn something new. In fact, over the past ten years, a number of AI systems have emerged that have passed the test one way or another in chat conversations with automatically generated texts or images. Nowadays, the discussion usually centers on other questions: Does AI still need its creators? Will it not only outperform humans but someday replace them – be it in the world of work or even beyond? Will AI solve our problems in the age of all-encompassing digital networking – or will it become a part of the problem? Artificial intelligence, its nature, its limitations, its potential, and its relationship to humans were being discussed even before it existed. Literature and film have created scenarios with very different endings. But what is the view of the scientists who are actually researching with or about artificial intelligence? For the current issue of our research magazine, a cognitive scientist, an education researcher, and a computer scientist shared their views. We also searched the University for projects whose professional environment reveals the numerous opportunities that AI offers for various disciplines. We cover the geosciences and computer science as well as economics, health, and literature studies. At the same time, we have not lost sight of the broad research spectrum at the University: a legal expert introduces us to the not-so-distant sphere of space law while astrophysicists work on ensuring that state-of-the-art telescopes observe those regions in space where something “is happening” at the right time. A chemist explains why the battery of the future will come from a printer, and molecular biologists explain how they will breed stress-resistant plants. You will read about all this in this issue as well as about current studies on restless legs syndrome in children and the situation of Muslims in Brandenburg. Last but not least, we will introduce you to the sheep currently grazing in Sanssouci Park – all on behalf of science. Quite clever! Enjoy your read! THE EDITORS T3 - Portal Wissen: The research magazine of the University of Potsdam [Englische Ausgabe] - 01/2019 Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-442469 SN - 2198-9974 IS - 01/2019 CY - 54 ER - TY - JOUR A1 - Hassler, Gerda A1 - Wilkens, Martin A1 - Scheerer-Neumann, Gerheid A1 - Kretschmann, Martina A1 - Resch-Esser, Ursula A1 - Wagner, Karen A1 - Pabst, Markus T1 - Portal = Nach PISA: Reformbedarf auch für die Lehrerbildung BT - Die Potsdamer Universitätszeitung N2 - Aus dem Inhalt: - Nach PISA: Reformbedarf auch für die Lehrerbildung - Neue Regelungen im Hochschulrahmengesetz - Bunsen-Gesellschaft für Pysikalische Chemie tagt in Potsdam - Abschied: Neue Aufgaben für Barbara Schneider-Kempf T3 - Portal: Das Potsdamer Universitätsmagazin - 03-04/2002 Y1 - 2002 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-439583 SN - 1618-6893 EP - 03-04/2002 ER - TY - JOUR A1 - Görlich, Petra A1 - Horn-Conrad, Antje A1 - Kampe, Heike A1 - Zimmermann, Matthias A1 - Scholz, Jana A1 - Engel, Silke A1 - Schneider, Simon T1 - Portal Wissen = Cosmos BT - The Research Magazine of the University of Potsdam N2 - Speaking of the cosmos means speaking about nothing less than everything, about the entirety of space filled with matter and energy. We only see a tiny fraction of it from Earth: planets like Venus or stars like the Sun. There are at least 100 billion stars in our home galaxy alone. Bound by gravity, these luminescent celestial bodies of very hot gas form a system visible from Earth as a whitish ribbon, which we call the Milky Way. The observable cosmos contains at least 100 billion such galaxies with stars, cosmic dust, gas, and probably dark matter as well. The universe is 13.8 billion years old; crossing it once would probably take 78 billion light-years. Given these dimensions, it is hardly surprising that for us humans, the mystery of the properties of the cosmos is connected with questions of being. Where do we come from? Where are we going? Are we alone in the universe? Such questions are in the wheelhouse of astrophysicists, who explore the vastness of the cosmos through physical means, even though they, of course, deal with physical laws, mathematical formulas, and complicated measuring methods. In this issue of Portal Wissen, we talked with astrophysicists at the University of Potsdam about their research and everyday work. Lutz Wisotzki showed us a 3D spectrograph, which he has developed in collaboration with colleagues from the Leibniz Institute for Astrophysics (AIP) and six other European institutes. This technical masterpiece enables scientists to look deeply into space and to “journey” through time to galaxies shortly after the Big Bang. Philipp Richter introduced us to the astrophysics research initiative and demonstrated how the University of Potsdam is working together with the AIP, the Albert Einstein Institute (AEI) and the Deutsches Elektronen-Synchrotron (DESY) to train junior researchers. The newly appointed Professor of Stellar Astrophysics, Stephan Geier, presented us with stars so close together to each other that they appear to be one to the naked eye. The physicist, who is also a historian, researches their turbulent relationships. We have not confined ourselves to cosmic themes, though, but also questioned rather earthly matters such as modern consumption. We have thought about potential love relationships with robots and testimonials in literature and art. We learned why the rainforest in Central Africa disappeared 2,600 years ago, how to produce knee prostheses on a production line, and how animals in the field benefit from big data. But back to the cosmos. The writing of late astrophysicist Stephen Hawking fundamentally shaped our concepts and knowledge of the universe. And that is because he was both an important physicist and a literary genius. Hardly anyone has been able to capture difficult facts in such a clear, understandable, and beautiful language. With this exemplary understanding of science in mind, we hope to offer you a stimulating read. The Editors T3 - Portal Wissen: The research magazine of the University of Potsdam [Englische Ausgabe] - 02/2018 Y1 - 2018 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-441674 SN - 2198-9974 IS - 02/2018 ER - TY - JOUR A1 - Zimmermann, Matthias A1 - Scholz, Jana A1 - Eckardt, Barbara A1 - Kampe, Heike A1 - Görlich, Petra A1 - Horn-Conrad, Antje T1 - Portal Wissen = Language BT - The Research Magazine of the University of Potsdam N2 - Language is perhaps the most universal tool of human beings. It enables us to express ourselves, to communicate and understand, to help and get help, to create and share togetherness. However, that does not completely capture the value of language. “Language belongs to the character of man,” said the English philosopher Sir Francis Bacon. If you believe the poet Johann Gottfried von Herder, a human is “only a human through language”. Ultimately, this means that we live in our world not with, but in, language. We not only describe our reality by means of language, but language is the device through which we open up the world in the first place. It is always there and shapes and influences us and the way we perceive, analyze, describe and ultimately determine everything around us. Since it is so deeply connected with human nature, it is hardly surprising that our language has always been in the center of academic research – and not only in those fields that bear the name linguistics. Philosophy and media studies, neurology and psychology, computer science and semiotics – all of them are based on linguistic structures and their premises and possibilities. Since July 2017, a scientific network at the University of Potsdam has been working on exactly this interface: the Collaborative Research Center “Limits of Variability in Language” (SFB 1287), funded by the German Research Foundation (DFG). Linguists, computer scientists, psychologists, and neurologists examine where language is or is not flexible. They hope to find out more about individual languages and their connections. In this issue of Portal Wissen, we asked SFB spokeswoman Isabell Wartenburger and deputy spokesman Malte Zimmermann to talk about language, its variability and limits, and how they investigate these aspects. We also look over the shoulders of two researchers who are working on sub-projects: Germanist Heike Wiese and her team examine whether the pandemonium of the many different languages spoken at a weekly market in Berlin is creating a new language with its own rules. Linguist Doreen Georgi embarks on a typological journey around the world comparing about 30 languages to find out if they have common limits. We also want to introduce other research projects at the University of Potsdam and the people behind them. We talk to biologists about biodiversity and ecological dynamics, and the founders of the startup “visionYOU” explain how entrepreneurship can be combined with social responsibility. Other discussions center round the effective production of antibodies and the question of whether the continued use of smartphones will eventually make us speechless. But do not worry: we did not run out of words – the magazine is full of them! Enjoy your reading! The Editors T3 - Portal Wissen: The research magazine of the University of Potsdam [Englische Ausgabe] - 01/2018 Y1 - 2018 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-441666 SN - 2198-9974 IS - 01/2018 ER - TY - JOUR A1 - Kampe, Heike A1 - Zimmermann, Matthias A1 - Horn-Conrad, Antje A1 - Scholz, Jana A1 - Eckardt, Barbara T1 - Portal Wissen = Earth BT - The Research Magazine of the University of Potsdam N2 - Earth’s surface is constantly changing. It is the synergetic overlap between the geosphere, biosphere, and climatic sphere and influences the development of our planet. It is our habitat and plays a key role in maintaining the wellbeing of humanity. Many aspects of this system as a whole, however, are not yet understood. This needs to change immediately because there is not much time left for the Earth – or for us. Photographer and filmmaker Yann Arthus- Bertrand warned in 2009, “In less than 200 years we have disturbed the balance of the Earth that has been created in over four billion years.” Potsdam and Berlin geoscientists, biologists, and climatologists have now joined forces*: They are investigating processes of the Earth's surface in order to better understand them on various spatial and time scales and to predict how our living environment will develop. In this issue of the research magazine “Portal Wissen”, we present some of the research projects as well as the researchers who drive them. We followed researchers to Ethiopia – to the “cradle of humankind” – where elaborate drilling is offering a glimpse into climate history. Analyses of the several-hundred-thousand- year old deposits provide insights not only for geological and climate researchers. Biologists were able to reconstruct how entire ecosystems developed over long periods using state-of-the-art genetic analysis. A geomicrobiologist shows us the vast insight you get when you cross disciplinary boundaries. His research is no longer taking place on and in the earth but even in outer space. The young researchers of the research training group StRatGy cut large boulders from the Argentinean Andes into the thinnest of slices in order to understand how the mountains developed. And a data analysis expert explains why it is not enough to collect and feed a lot of data into a computer; they also have to be made readable using the right analytic tools. “The world is a fine place and worth the fighting for,” wrote Ernest Hemingway. This is exactly what researchers are doing when they look for solutions to prevent humanity from irreversibly damaging the Earth. We met a researcher who is working with colleagues throughout Europe to learn more about trace elements and using plants as pollutant “vacuum cleaners”. And it was explained to us how satellite images taken from afar are revolutionizing nature conservation. The diversity of research at the University of Potsdam should not be forgotten. We followed administrative scientists on the trail of successful reforms around the world and we looked at how reading can be more successful. We asked what supplementary extracurricular lessons can offer (or not offer) and looked into the networked classroom of the future. Germanists also revealed their Brandenburg linguistic treasures to us, psychologists showed us their experiments, and a historian explained to us why the MfS – the GDR state security ministry – were active as development workers. Last but not least, we visited a chemist in the lab, were introduced to the language of climate images, and listened to a romance philologist who researches with all her senses. Enjoy your read! The Editors T3 - Portal Wissen: The research magazine of the University of Potsdam [Englische Ausgabe] - 02/2017 Y1 - 2017 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-441652 SN - 2198-9974 IS - 02/2017 ER - TY - JOUR A1 - Kampe, Heike A1 - Zimmermann, Matthias A1 - Scholz, Jana A1 - Görlich, Petra A1 - Eckardt, Barbara T1 - Portal Wissen = rich BT - The Research Magazine of the University of Potsdam N2 - The current Issue of Portal Wissen is entitled “reich”, a German word with several meanings. Both an adjective and a noun, it can be translated as rich, wealthy, and abundant, or realm, empire, and kingdom. It is also part of words like Reichtum (wealth, fortune), Reichweite (reach, scope), lehrreich (informative, instructive) and ruhmreich (glorious, renowned*). Realms – a complex subject. While the worldly empires of mankind come and go, even if they often claim the opposite, and the eternal existence of the kingdom of heaven has not been credibly proven, another and much older realm has an almost inexhaustible wealth – the animal and plant kingdom. Speaking of wealth: Some people are rich and want to stay rich at any price. Others still want to become rich and are looking for a path to wealth – some for the fastest, some for the easiest, and some for the perfect path. There are even people who want to leave nothing to chance and use a scientific approach, for example the American author Wallace D. Wattles, who published the book The Science of Getting Rich in 1903. His essay was intended for “for the men and women whose most pressing need is for money; who wish to get rich first, and philosophize afterward.” He was so convinced of his work that he even offered a guarantee of success. Anyone who followed his manual would “undoubtedly become rich because the science that is used here is an exact science, and failure is impossible.” Wattles has been almost forgotten, but the secret of wealth – at least financial wealth – seems anything but deciphered. Some have got it, others want it. There are worlds in between – as well as envy, prejudices and ignorance. More than enough reason for us to look again at Wallace D. Wattles and his self-confidently presented alleged relationship between wealth and science, and to say: Yes! Of course, science makes us rich, but primarily rich in perception, experience and – in knowledge. Science in itself is not glorious but instructive. The great thing is: All can equally benefit from the wealth created by science at the same time. Nobody has to get rich at the expense of others, on the contrary: You can often achieve much more together with others. Everything else comes (almost) by itself. “Those who acquire knowledge are richly rewarded by God,” is the religiously informed praise of sciences by the Islamic prophet Muhammad. The current issue of the Portal Wissen, however, focuses on facts, which is admittedly not in style at the moment. We therefore invite you to a tour of the University of Potsdam and its partners. It is about studies on the rich biodiversity of porpoises and lab mice. We present a historian who studies rich church treasures and talk with an education researcher about the secret of financial wealth. German philologists explain the rich language of literary criticism in the era of Enlightenment, and we follow a geo-scientist into the mountains where he moved large boulders to find the right stones. It is also about the cities of tomorrow, which have many high-rise buildings but are still (rich in) green, abundant water from once-in-acentury flash floods, and insects as an alternative to a rich diet of tomorrow. We take you to the border area of two disciplines where law and philosophy work hand in hand, talk with two literary scholars who are studying the astounding reach of the Schlager phenomenon of traditional German-language pop music, and learn from a sustainability researcher how to work together to achieve long-term solutions for pressing global problems. We wish you a pleasant read! The Editors T3 - Portal Wissen: The research magazine of the University of Potsdam [Englische Ausgabe] - 01/2017 Y1 - 2017 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-441642 SN - 2198-9974 IS - 01/2017 ER - TY - JOUR A1 - Kampe, Heike A1 - Scholz, Jana A1 - Zimmermann, Matthias A1 - Eckardt, Barbara A1 - Horn-Conrad, Antje T1 - Portal Wissen = small BT - The Research Magazine of the University of Potsdam N2 - Let’s be honest: even science wants to make it big, at least when it comes to discovering new knowledge. Yet if one thing belongs in the annals of successful research, it is definitely small things. Scientists have long understood that their job is to explore things that they don’t see right away. Seneca once wrote, “If something is smaller than the great, this does not mean at all that it is insignificant.” The smallest units of life, such as bacteria or viruses, can often have powerful effects. And again and again, (seemingly) large things must first be disassembled or reduced to small pieces in order to recognize their nature. One of the greatest secrets of our world – the atom, the smallest, if no longer indivisible, unit of chemical elements – revealed itself only by looking at its diminutive size. By no means is ‘small’ (German: klein) merely a counterpoint to large, at least in linguistic terms; the word comes from West Germanic klaini, which means ‘fine’ or ‘delicate,’ and is also related to the English word ‘clean.’ Fine and clean – certainly something worth striving for in scientific work. And a bit of attention to detail doesn’t hurt either. This doesn’t mean that researchers can be smallminded; they should be ready to expect the unexpected and to adjust their work accordingly. And even if they cannot attain their goals in the short term, they need staying power to keep themselves from being talked down, from giving up. Strictly speaking, research is like putting together a puzzle with tons of tiny pieces; you don’t want it to end. Every discovery worthy of a Nobel Prize, every major research project, has to start with a small idea, with a tiny spark, and then the planning of the minutest details can begin. What follows is work focused on minuscule details: hours of interviews searching for the secret of the cerebellum (Latin for ‘little brain’), days of field studies searching for Lilliputian forms of life, weeks of experimentation meant to render visible the microscopically tiny, months of archival research that brings odds and ends to light, or years of reading fine print. All while hunting for a big hit... This is why we’ve assembled a few ‘little’ stories about research at the University of Potsdam, under the motto: small, but look out! Nutritional scientists are working on rescuing some of the earth’s smaller residents – mice – from the fate of ‘lab rats’ by developing alternatives to animal testing. Linguists are using innovative methods in several projects to investigate how small children learn languages. Astrophysicists in Potsdam are scanning the skies above Babelsberg for the billions of stars in the Magellan Cloud, which only seem tiny from down here. The Research Center Sanssouci, initiated by the Prussian Palaces and Gardens Foundation and the University of Potsdam, is starting small but will bring about great things for Potsdam’s cultural landscape. Biologists are drilling down to the smallest building blocks of life, looking for genes in barley so that new strains with positive characteristics can be cultivated. Like we said: little things. Have fun reading! The Editorial T3 - Portal Wissen: The research magazine of the University of Potsdam [Englische Ausgabe] - 02/2016 Y1 - 2016 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-441621 SN - 2198-9974 IS - 02/2016 ER - TY - JOUR A1 - Kampe, Heike A1 - Zimmermann, Matthias A1 - Scholz, Jana A1 - Görlich, Petra A1 - Engel, Silke T1 - Portal Wissen = Point BT - The Research Magazine of the University of Potsdam N2 - A point is more than meets the eye. In geometry, a point is an object with zero dimensions – it is there but takes up little space. You may assume that something so small is easily overlooked. A closer look reveals that points are everywhere and play a significant role in many areas. In physics, for example, a mass point is the highest possible idealization of a body, which is the theoretical notion that the entire mass of a body is concentrated in a point, its “center of mass”. Points are at the beginning (starting points), at intersections (pivot points), and at the end (final points). A point symbolizes great precision. There is a reason we “get to the point”. In writing, a point abbreviates, structures, and finalizes what is said. Physicians puncture, and athletes collect points on playing fields, courses, and on tables. It’s no wonder that researchers are “surrounded” by points and work with them every day: Points bring order to chaos, structure the unexplained, and name the nameless. A point is often the beginning, an entry to worlds, findings, or problems. Points are for everyone, though. German mathematician Oskar Perron wrote, “A point is exactly what the intelligent yet innocent, uncorrupted reader imagines it to be.” We want to follow up on this quotation: The latest edition of Portal Wissen offers exciting starting points, analyzes points of view, and gets right to the point. We follow a physicist to the sun – the center point of our solar system – to ponder the origin of solar eruptions. We talked to a marketing professor about turning contentious points into successful deals during negotiation. Business information experts present leverage points that prepare both humans and machines for factories in the age of Industry 4.0. Enthusiastic entrepreneurs show us how their research became the starting point of a successful business idea – and also make the world a bit better. Geoscientists explain why the weather phenomenon El Niño causes – wet and dry – flashpoints. Just to name a few of many points … We hope our magazine scores points with you and wish you an inspiring read! The Editorial T3 - Portal Wissen: The research magazine of the University of Potsdam [Englische Ausgabe] - 01/2016 Y1 - 2016 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-441569 SN - 2198-9974 IS - 01/2016 ER - TY - JOUR A1 - Kimminich, Eva A1 - Jäger, Heidi A1 - Horn-Conrad, Antje A1 - Scholz, Jana A1 - Zimmermann, Matthias A1 - Kampe, Heike T1 - Portal Wissen = Signs BT - The Research Magazine of the University of Potsdam N2 - Signs take a variety of forms. We use or encounter them every day in various areas. They represent perceptions and ideas: A letter represents a sound, a word or picture stands for an idea, a note for a sound, a chemical formula for a substance, a boundary stone for a territorial claim, a building for an ideology, a gesture for a cue or an assessment. On the one hand, we open up the world to ourselves by using signs; we acquire it, ensconce ourselves in it, and we punctuate it to represent ourselves in it. On the other, this reference to the world and ourselves becomes visible in our sign systems. As manifestations of a certain way of interacting with nature, the environment, and fellow human beings, they provide information about the social order or ethnic distinctions of a certain society or epoch as well as about how it perceives the world and humanity. As a man-made network of meanings, sign systems can be changed and, in doing so, change how we perceive the world and humanity. Linguistically, this may, for example, be done by using an evaluative prefix: human – inhuman, sense – nonsense, matter – anti-matter or by hierarchizing terms, as in upper class and lower class. The consequences of such labeling, therefore, may decide on the raison d'être of the signified within an aspect of reality and the nature of this existence. Since ancient times we have reflected on signs, at first mainly in philosophy. Each era has created theories of signs as a means of approaching its essence. Nowadays semiotics is especially concerned with them. While linguistics focuses on linguistic signs, semiotics deals with all types of signs and the interaction of components and processes involved in their communication. Semiotics has developed models, methods, and concepts. Semiosis and semiosphere, for example, are concepts that illuminate the processing of signs, i.e. the construction of meaning and the interaction of different sign systems. A sign is not limited to a monolithic meaning but is culturally contingent and marked by the socioeconomic conditions of the individual decoding it. Sociopolitical and sociocultural developments therefore affect the processing of signs. Dealing with signs and sign systems, their circulation, and reciprocal play with shapes and interpretive possibilities is therefore an urgent and trailblazing task in light of sociocultural communication processes in our increasingly heterogeneous society to optimize communication and promote intercultural understanding as well as to recognize, use, and bolster social trends. The articles in this magazine illustrate the many ways academia is involved in researching, interpreting, and explaining signs. Social scientists at the University of Potsdam are examining whether statistics about petitions made by GDR citizens can be interpreted retrospectively as a premonitory sign of the peaceful revolution of 1989. Colleagues at the Institute of Romance Studies are analyzing what Alexander von Humboldt’s American travel diaries signalize, and young researchers in the Research Training Group on “Wicked Problems, Contested Administrations” are examining challenges that seem to raise question marks for administrations. A project promoting sustainable consumption hopes to prove that academia can contribute to setting an example. An initiative of historians supporting Brandenburg cities in disseminating the history of the Reformation shows that the gap between academia and signs and wonder is not unbridgeable. I wish you an inspiring read! Prof. Dr. Eva Kimminich Professor of Romance Cultural Studies T3 - Portal Wissen: The research magazine of the University of Potsdam [Englische Ausgabe] - 02/2015 Y1 - 2015 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-441553 SN - 2198-9974 IS - 02/2015 ER - TY - JOUR A1 - Müller-Röber, Bernd A1 - Zimmermann, Matthias A1 - Eckardt, Barbara A1 - Jäger, Heidi A1 - Kampe, Heike A1 - Horn-Conrad, Antje A1 - Jäger, Sophie T1 - Portal Wissen = Paths BT - The Research Magazine of the University of Potsdam N2 - How traits are inherited from one generation to the next, how mutations change genetic information and consequently contribute to the development of new characteristics and emergence of new species – all these are exciting biological questions. Over millions of years, genetic differentiation has brought about an incredible diversity of species. Evolution has followed many different paths. It has led to an awesome natural biodiversity – to organisms that have adapted to very different environments and are sometimes oddly shaped or behave strangely. Humanmade biodiversity is stunning, too. Just think of the 10,000 rose varieties whose beauty delights, or the myriad wheat, barley, and corn variations; plants that had all once been plain grasses feed us today. We humans create our own biodiversity unknown to nature. And it is serving us well. Thanks to genome research we are now able to read the complete genetic information of organisms within a few hours or days. It takes much longer, however, to functionally map the many genomic sequences. Researchers achieve this through various methods: Activating or deactivating genes systematically, modifying their code, and exchanging genetic information between organisms have become standard procedures worldwide. The path to knowledge is often intricate, though. Elaborate experimental approaches are often necessary to gain insight into biological processes. Methods of genomic research enable us to investigate not only what is “out there” in nature, but also to ask, “How does a living organism, like a moss, react when sent to the International Space Station (ISS)? Can we gain knowledge about the adaptation strategies of living beings in harsh environmental conditions or even for colonizing the Moon or Mars?” Can we use synthetic biology to precisely alter microorganisms, planned on a drawing board so to speak, to create new options for treating diseases or for making innovative biology-based products? The answer to both questions is a resounding Yes! (Although moving to other planets is not on our present agenda.) Human land use determines biodiversity. On the other hand, organisms influence the formation of landscapes and, sooner or later, the composition of our atmosphere. This also leads to exciting scientific questions. Researchers have to strike new paths to reach new conclusions. Paths often cross other paths. A few years ago it was still unforeseeable that ecological research would substantially benefit from fast DNA sequencing methods. Genome researchers could hardly assume that the same techniques would lead to new possibilities for examining the highly complex cellular regulation and optimizing biotechnological processes. You will find examples of the multi-faceted research in biology as well as other very interesting articles in the latest edition of Portal Wissen. I wish you an enjoyable read! Prof. Dr. Bernd Müller-Röber Professor of Molecular Biology T3 - Portal Wissen: The research magazine of the University of Potsdam [Englische Ausgabe] - 01/2015 Y1 - 2015 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-441506 SN - 2198-9974 IS - 01/2015 ER - TY - JOUR A1 - Wilkens, Martin A1 - Sütterlin, Sabine A1 - Kampe, Heike A1 - Eckardt, Barbara A1 - Jäger, Sophie A1 - Zimmermann, Matthias T1 - Portal Wissen = Time BT - The Research Magazine of the University of Potsdam N2 - “What then is time?”, Augustine of Hippo sighs melancholically in Book XI of “Confessions” and continues, “If no one asks me, I know; if I want to explain it to a questioner, I don’t know.” Even today, 1584 years after Augustine, time still appears mysterious. Treatises about the essence of time fill whole libraries – and this magazine. However, questions of essence are alien to modern sciences. Time is – at least in physics – unproblematic: “Time is defined so that motion looks simple”, briefly and prosaically phrased, waves goodbye to Augustine’s riddle and to the Newtonian concept of absolute time, whose mathematical flow can only be approximately recorded with earthly instruments anyway. In our everyday language and even in science we still speak of the flow of time but time has not been a natural condition for quite a while now. It is rather a conventional order parameter for change and movement. Processes are arranged by using a class of processes as a counting system in order to compare other processes and to organize them with the help of the temporary categories “before”, “during”, and “after”. During Galileo’s time one’s own pulse was seen as the time standard for the flight of cannon balls. More sophisticated examination methods later made this seem too impractical. The distance-time diagrams of free-flying cannon balls turned out to be rather imprecise, difficult to replicate, and in no way “simple”. Nowadays, we use cesium atoms. A process is said to take one second when a caesium-133 atom completes 9,192,631,770 periods of the radiation corresponding to the transition between two hyperfine levels of the ground state. A meter is the length of the path travelled by light in a vacuum in exactly 1/299,792,458 of a second. Fortunately, these data are hard-coded in the Global Positioning System GPS so users do not have to reenter them each time they want to know where they are. In the future, however, they might have to download an app because the time standard has been replaced by sophisticated transitions to ytterbium. The conventional character of the time concept should not tempt us to believe that everything is somehow relative and, as a result, arbitrary. The relation of one’s own pulse to an atomic clock is absolute and as real as the relation of an hourglass to the path of the sun. The exact sciences are relational sciences. They are not about the thing-initself as Newton and Kant dreamt, but rather about relations as Leibniz and, later, Mach pointed out. It is not surprising that the physical time standard turned out to be rather impractical for other scientists. The psychology of time perception tells us – and you will all agree – that the perceived age is quite different from the physical age. The older we get the shorter the years seem. If we simply assume that perceived duration is inversely related to physical age and that a 20-year old also perceives a physical year as a psychological one, we come to the surprising discovery that at 90 years we are 90 years old. With an assumed life expectancy of 90 years, 67% (or 82%) of your felt lifetime is behind you at the age of 20 (or 40) physical years. Before we start to wallow in melancholy in the face of the “relativity of time”, let me again quote Augustine. “But at any rate this much I dare affirm I know: that if nothing passed there would be no past time; if nothing were approaching, there would be no future time; if nothing were, there would be no present time.” Well, – or as Bob Dylan sings “The times they are a-changin”. I wish you an exciting time reading this issue. Prof. Martin Wilkens Professor of Quantum Optics T3 - Portal Wissen: The research magazine of the University of Potsdam [Englische Ausgabe] - 02/2014 Y1 - 2014 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-441497 SN - 2198-9974 IS - 02/2014 ER -