Hoe kiezen we wat de school moet meegeven aan de volgende generatie, als elke groep in de samenleving daar anders over denkt? Waarom mag de één wel met steun van de overheid programma's maken voor... Show moreHoe kiezen we wat de school moet meegeven aan de volgende generatie, als elke groep in de samenleving daar anders over denkt? Waarom mag de één wel met steun van de overheid programma's maken voor omroep of theater, en de ander niet? Wat moet worden onderzocht als niet elk onderzoek kan worden betaald? In een land waar geen enkele meerderheid zomaar zijn wil kan opleggen, zijn dat lastige vragen. "In de regel vrij" laat zien hoe Nederland in de afgelopen eeuw op eigen wijze vorm gaf aan onderwijs, cultuur en wetenschap. Een bijzondere ervaring, die bij de vraagstukken van de toekomst nog van nut kan zijn. Dit toegankelijke en rijk geïllustreerde boek verschijnt bij het honderdjarig bestaan van het ministerie van Onderwijs, Cultuur en Wetenschap. Het beschrijft een eeuw in thema's, van burgerschap tot wetenschap en van media tot Mammoetwet. Daarnaast bevat het bijzondere interviews met alle oud-ministers sinds 1973. Show less
Mazepus, H.; Toshkov, D.D.; Chulitskaya, T.; Ramasheuskaya, I. 2017
Scientific cooperation between the European Union (EU) and its Eastern neighbours has grown rapidly since the early 2000s. This cooperation holds great promise to influence not only the science and... Show moreScientific cooperation between the European Union (EU) and its Eastern neighbours has grown rapidly since the early 2000s. This cooperation holds great promise to influence not only the science and innovation sectors, but also to affect the practices and values of research communities in the Eastern Partnership (EaP) countries, their public policies, and societies at large. In this paper we aim to assess the impact of scientific cooperation with the EU with a focus on three countries of the EaP: Belarus, Moldova, and Ukraine. Our analysis is divided into two parts: first, we focus on the scientific impact and conduct a bibliometric analysis that tracks several important indicators of the scientific output of Belarus, Moldova, and Ukraine for the period of 2000-2016; second, we address the broader impact on the scientific community, institutions, and society by analysing new data from expert interviews. In terms of scientific output we find that while the EU has not radically transformed science in the EaP countries it might have provided it with an essential lifeline of support. We also uncover clear evidence for positive impact of cooperation with the EU on the participating institutions from the EaP countries, but very little evidence (so far) about effects on public policies or significant impact on society at large. Show less
Scientific cooperation is an important part of the European Union (EU)’s policy approach towards the countries in its neighbourhood. This has opened up many opportunities for cooperation in the... Show moreScientific cooperation is an important part of the European Union (EU)’s policy approach towards the countries in its neighbourhood. This has opened up many opportunities for cooperation in the areas of science, technology, research, and innovation between the EU and the Eastern Partnership (EaP) countries. This working paper reviews the institutional and policy parameters of scientific cooperation between the EU and three EaP countries – Belarus, Moldova, and Ukraine. It provides an overview of the science policies in these countries, focusing on the lasting impact of their shared communist legacies and post-Soviet transitions, as well as on their current strategies, institutions, and ambitions in the domain of science, research and development policy. The paper also reviews the place of scientific cooperation in the EU’s science and external policies, focusing on relations with the neighbourhood and the EaP countries in particular. We also take stock of the existing programmes for scientific and educational cooperation and academic mobility between the EU and EaP countries. We present an inventory of relevant projects, with a discussion of the progress, level of participation of the research communities in the EaP, and other relevant parameters, such as the distribution of projects and participating institutions across broad scientific fields as well as disciplines. Altogether, we find that Belarus, Moldova, and Ukraine have registered a considerable degree of participation in the science and research programmes of the EU, but we also identify a number of barriers and structural impediments to a more successful partnership. Show less
The European Union and its member states are being urged by leading scientists to make a major multi million Euro commitment to solar driven production of environmentally clean electricity,... Show moreThe European Union and its member states are being urged by leading scientists to make a major multi million Euro commitment to solar driven production of environmentally clean electricity, hydrogen and other fuels, as the only sustainable long-term solution for global energy needs. The most promising routes to eventual full-scale commercial solar energy conversion directly into fuels were identified at a recent international meeting in Regensburg, sponsored by the European Science Foundation (ESF). An interdisciplinary task force was established at this meeting to make the case for substantial investments in these technologies to EU and national government decision makers. This report summarizes the outcome of this meeting. The fundamental issue is that total annual global energy consumption is set at least to double from its current level of 14 TW by 2050, while fossil fuels will start to run out and in any case would produce unacceptable levels of carbon dioxide, bringing global warming accompanied by disastrous effects in many areas, such as food production. Apart from solar energy, the shortfall can only be made up by renewable sources such as wind, along with the other nonfossil, non-renewable fuel source of energy, nuclear. But these will be unable to satisfy the expected increased energy needs, let alone replace fossil fuels entirely, even for electricity production. Another problem is that they will not readily yield stored fuels. Without an unexpected breakthrough in electricity storage, there will be a continued need for fuels for around 70% of total global energy requirements, particularly in transportation, manufacturing,and domestic heating. Electricity only accounts for 30% of global energy consumption at present. Solar energy, however, is plentiful since enough reaches the Earth’s surface every hour to meet the world’s annual energy needs. The problem lies in harnessing it, but nature has perfected in photosynthesis a highly efficient and flexible means of doing this across a wide variety of scales from isolated bacterial colonies to large forests. Substantial progress has been made recently, particularly in Europe, to understand and mimic these processes, sufficient for scientists to be confident that it can work to produce fuels on a commercial scale. The focus of research therefore should be on drawing inspiration from biological systems for the creation of both natural and artificial solar energy conversion systems that allow in the long run for a stable and sustainable energy supply. The focus should also be on reducing the ecological footprint of the human economy and thereby increasing the global ecological capacity using technology that is environmentally clean, for instance by conversion of carbon dioxide back into fuels in a cyclic process. The ESF task force is recommending that three parallel avenues of solar energy research for generating clean fuel cycles should be pursued in Europe: 1) Extending and adapting current photovoltaic technology to generate clean fuels directly from solar radiation. 2) Constructing artificial chemical and biomimetic devices mimicking photosynthesis to collect, direct, and apply solar radiation, for example to split water, convert atmospheric carbon dioxide and thus produce various forms of environmentally clean fuels. 3) Tuning natural systems to produce fuels such as hydrogen and methanol directly rather than carbohydrates that are converted into fuels in an indirect and inefficient process. These three research themes will overlap, and all will exploit fundamental research elucidating the precise molecular mechanisms involved in the splitting of water into hydrogen and oxygen in photosynthesis by both plants and bacteria. This process, which evolved 2.5 billion years ago, created the conditions for animal life by converting atmospheric carbon dioxide into carbohydrates, and also produced all the fossil fuels, which humans are turning back into carbon dioxide at an increasing rate, threatening catastrophic environmental effects. The same process now holds our salvation again. Although the principal products of photosynthesis in plants and bacteria are carbohydrates, certain algae and cyanobacteria can produce hydrogen directly from water using sunlight, providing a basis for genetic modification to increase yields, and for the creation of suitable artificial systems. Furthermore, photosynthesis is also capable of generating other chemicals currently made industrially, such as nitrates, and other high value compounds for chemical industry. The European research program will therefore also seek to develop systems for converting solar energy directly into such chemicals with much greater efficiency, offering the prospect not just of producing unlimited energy, but also fixing atmospheric carbon dioxide to bring concentrations back down to pre-industrial levels as part of the overall thrust for clean renewable energy. There are considerable challenges, with the first being to mimic the functioning of natural photosynthetic systems, particularly photosystem II, the enzyme complex in the leaves of plants that splits water into hydrogen and oxygen via a catalyst comprising four manganese atoms along with some calcium. Significant progress has been made recently on this front. Participants at the ESF’s brainstorming conference, describe the solar fuels project as the quest for building the “artificial leaf”. There is growing conviction in Europe and elsewhere that by 2050 a large proportion of our fuels will come from such “artificial leaves” and that there is no time to lose starting the crucial enabling research, in order to gain technology leadership in this important future key technology. Show less
