How do global audiences use streaming platforms like YouTube, Netflix and iPlayer? How does the experience of digital video change according to location? What strategies do people use to access out-of-region content? What are the commercial and governmental motivations behind geoblocking?Geoblocking and Global Video Culture explores the cultural implications of access control and circumvention in an age of VPNs. Featuring seventeen chapters from diverse critical positions and locations – including China, Iran, Malaysia, Turkey, Cuba, Brazil, USA, Sweden and Australia.
AbstractHistorically, epidemics and plagues are repeatedly reported to have happened since the ancient civilizations (Egypt, Greece, Rome and imperial China). Most known examples of a devastating global pandemics in recent history are the ‘Black Death’ (14th century) and the global influenza (1918-1919), also known as ‘Spanish Flu’, that has killed nearly 50 million people in the world. Even thoughpandemics may vary in their dimensions, length (short vs. long), scope (local/regional, national, global) and severity of effects (minimal effects or maximal effects), they all represent distinct exogenous and endogenous shocks that have far reaching effects on population, health, economy and other societal domains.Currently, the Covid-19 pandemic has relentlessly spreaded around the world, leaving behind destructive marks on health, populations, economies and societies. The Covid-19 could spread quickly around the globe because of the current structure of the global economy, which is highly interconnected through sophisticated global transport networks. An important characteristic of a suchnetworked complex system is it vulnerability to unattended events of systemic risk such as the Covid-19 pandemic for example. These systemic risks cause substantial cascading effects, which lead to extreme outcomes that could permanently alter economic, environmental, and social systems.In this article, we first, present, discuss and analyze the potential impacts of the Covid-19 on global economy, trade and supply chains, by focusing on Europe and/or the Netherlands. Second, we examine the effects of the Covid-19 crisis on the shipping industry and on the hub ports and the policy measures that have been applied by different countries around the world.
The internationalization of higher education has been driven by an increasingly globalized and interconnected world. One concept that embodies this internationalization process is global citizenship, which can be promoted through student mobility, internationalization-at-home, or other forms of intercultural learning. While global citizenship remains a broad and highly contested term, the increased interest of its role in higher education has inspired research in different fields. The aim of this paper is to provide a review of existing research approaches to studying global citizenship, and to formulate future research directions that may integrate these approaches into a holistic framework. By reviewing literature from different fields in the social sciences, we have identified three main research approaches: intercultural competence, social identification with a global community, and civic engagement. While each approach reflects an important dimension of global citizenship, they remain separate in the literature, complicating the understanding and application of global citizenship in higher education. Therefore, for each approach we present a general conceptualization and a brief overview of prior findings. We discuss how integrating these approaches can lead to a more holistic understanding of global citizenship and guide future avenues for research and practice in higher education.
The Dutch floriculture is globally leading, and its products, knowledge and skills are important export products. New challenges in the European research agenda include sustainable use of raw materials such as fertilizer, water and energy, and limiting the use of pesticides. Greenhouse growers however have little control over crop growth conditions in the greenhouse at individual plant level. The purpose of this project, ‘HiPerGreen’, is to provide greenhouse owners with new methods to monitor the crop growth conditions in their greenhouse at plant level, compare the measured growth conditions and the measured growth with expected conditions and expected growth, to point out areas with deviations, recommend counter-measures and ultimately to increase their crop yield. The main research question is: How can we gather, process and present greenhouse crop growth parameters over large scale greenhouses in an economical way and ultimately improve crop yield? To provide an answer to this question, a team of university researchers and companies will cooperate in this applied research project to cover several different fields of expertise The application target is floriculture: the production of ornamental pot plants and cut flowers. Participating companies are engaged in the cultivation of pot plans, flowers and suppliers of greenhouse technology. Most of the parties fall in the SME (MKB) category, in line with the RAAK MKB objectives.Finally, the Demokwekerij and Hortipoint (the publisher of the international newsletter on floriculture) are closely involved. The project will develop new knowledge for a smart and rugged data infrastructure for growth monitoring and growth modeling in the greenhouse. In total the project will involve approximately 12 (teacher) researchers from the universities and about 60 students, who will work in the form of internships and undergraduate studies of interesting questions directly from the participating companies.
A fast growing percentage (currently 75% ) of the EU population lives in urban areas, using 70% of available energy resources. In the global competition for talent, growth and investments, quality of city life and the attractiveness of cities as environments for learning, innovation, doing business and job creation, are now the key parameters for success. Therefore cities need to provide solutions to significantly increase their overall energy and resource efficiency through actions addressing the building stock, energy systems, mobility, and air quality.The European Energy Union of 2015 aims to ensure secure, affordable and climate-friendly energy for EU citizens and businesses among others, by bringing new technologies and renewed infrastructure to cut household bills, create jobs and boost growth, for achieving a sustainable, low carbon and environmentally friendly economy, putting Europe at the forefront of renewable energy production and winning the fight against global warming.However, the retail market is not functioning properly. Many household consumers have too little choices of energy suppliers and too little control over their energy costs. An unacceptably high percentage of European households cannot afford to pay their energy bills. Energy infrastructure is ageing and is not adjusted to the increased production from renewables. As a consequence there is still a need to attract investments, with the current market design and national policies not setting the right incentives and providing insufficient predictability for potential investors. With an increasing share of renewable energy sources in the coming decades, the generation of electricity/energy will change drastically from present-day centralized production by gigawatt fossil-fueled plants towards decentralized generation, in cities mostly by local household and district level RES (e.g PV, wind turbines) systems operating in the level of micro-grids. With the intermittent nature of renewable energy, grid stress is a challenge. Therefore there is a need for more flexibility in the energy system. Technology can be of great help in linking resource efficiency and flexibility in energy supply and demand with innovative, inclusive and more efficient services for citizens and businesses. To realize the European targets for further growth of renewable energy in the energy market, and to exploit both on a European and global level the expected technological opportunities in a sustainable manner, city planners, administrators, universities, entrepreneurs, citizens, and all other relevant stakeholders, need to work together and be the key moving wheel of future EU cities development.Our SolutionIn the light of such a transiting environment, the need for strategies that help cities to smartly integrate technological solutions becomes more and more apparent. Given this condition and the fact that cities can act as large-scale demonstrators of integrated solutions, and want to contribute to the socially inclusive energy and mobility transition, IRIS offers an excellent opportunity to demonstrate and replicate the cities’ great potential. For more information see the HKU Smart Citieswebsite or check out the EU-website.
The objective of Sustainable Solid Biofuel project is to contribute to a zero-waste and low-carbon emission production of charcoal by evaluating the feasibility and energy efficiency of three different conversion technologies. According to the IEA’s World Energy Outlook 2015 3 billion (more than a third of the global population) use solid biomass as wood, charcoal, or animal waste for cooking and heating1. Charcoal is one of the most widely used of the solid biofuels. In current charcoal production processes the gas stream from pyrolysis are mostly directly released to the environment which wastes energy and causes serious environmental pollution. However, the production of charcoal can be improved to be practiced on a sustainable basis by careful selection of wood or alternative biomass source as wood waste or agricultural residues and further focusing on harvesting strategy and production techniques. In the conversion process it is necessary to increase the energy efficiency while reducing emissions. Further sustainability can be increased by processing the smoke that is exhausted from the kiln, that correspond to roughly one third of the whole biomass. Within the volatile components in the smoke there are chemicals which can be used, for example, as industrial cleaners or wood preservatives and thus one of the environmental drawbacks of charcoal production can be eliminated and turned into another product input. Brazil is the world's largest charcoal producer2 consequently the state of the art of the recearch in this field can be found in Brazil. In this Sustainable Solid Biofuels project one of the leading universities of Brazil, the Universidade Federal de Viçosa (UFV) is joining forces with Avans University of Applied Sciences and two Dutch SMEs Privium B.V. and Charcotec B.V. to carry out the evaluation of the improvements that can be achieved in the energy efficiency.
