Research and Development “R&D” has direct and indirect feedbacks and impacts on the global implementation, and also the successful achievements, of UN-SDG. One can expect that the UN-SDG can be achieved, and thereby implemented, as an Added-Value components to “R&D” Programs and Projects in cases where  they are clearly specified and defined by funding organisations and institutes. This in turn will generate stronger, active and vital engagement of universities, academies, researchers and education programs in the promotion and implementation of UN-SDG.  In particular shaping higher education, R&D for appropriate and timely promotion and implementation of the UN-SDG on local and regional scales with special focus on society and population needs. Also, with consideration to three pillars of sustainability (economic, social and environment issues) and building on the available natural resources in different regions. These are of course in addition to dedicated programs and projects where “R&D” directly deals with sustainability and sustainable developments in general. 

Currently, there are no exact, detailed and coordinated global assessment policies/strategies on when, how and where the UN-SDG are to be achieved, though there are fragmented data on such issues in limited counties and regions. However, some information can be indirectly extracted from the global view of R&D, so as to examine strengths and weaknesses in following-up and assessing the perfomance by sectors, products, technologies, markets, regions and countries.

Research and development (R&D) is defined as the process of creating new products, processes and technologies that can be used and marketed for mankind’s benefit in the future. What regards sustainability, the interests and needs of future generations have to be taken in considerations. As the R&D processes and their costs vary from industry to industry, from country to country and from year to year, we can expect wide-range of variations in effectiveness, performance and time-scales of relevance for UN-SDG.

R&D investment in Asian countries (e.g. Japan, India and South Korea) including China is currently accounting for more than 40% of all global R&D investments, the North American investments now less than 30% and European R&D only slightly more than 20%. The rest of the world (Russia, Africa, South America and the Middle East countries) account for a combined 8.8% of the global R&D investments with combined average growth of only about 1.5% per year. Much of the R&D growth in any country around the world is driven by that country’s economic growth.

There are substantial changes that are being seen in industrial R&D makeup. Life science R&D, for example, has been the largest sector in the industrial technology arena. However, the automotive arena is expected to grow their R&D programs due to strong technology shifts from internal combustion to electric propulsion systems, manual to automated driving systems and increasingly integrated electronic systems. Other changes include the rapid and mostly unexpected implementation of self-driving cars; the emergence of electric cars, which could supplant a significant portion of fossil fuel-powered vehicles in a relatively short period; and the availability of large amounts of fossil fuels at low prices not experienced in more than 20 years. Fast forward to today, unlike what was known before, there’s an oil glut on the world market, gas prices are where they were 25 years ago and the U.S. has considered exporting crude oil from its shale oil reserves. Saudi Arabia and other traditional oil exporting countries will be faced with serious economic difficulties because of low gas prices.

Solar-powered technologies continue to be a relatively small sector of the overall energy industry that is populated by comparatively smaller technology companies. Most of these small energy companies, with strong future market forecasts, expect to increase their R&D spending in 2016. Solar cells, power converters and associated hardware continue to improve in overall effiencies, while dropping lightly in overall prices. In the Automotive industry, lithium-ion batteries are improving which in combination with computers can bring about new trends in automotive markets. Solar-panel system, also for small industries and other consumer uses, can shape additional new trends. 

Except in the automotive arena, the U.S. industries gained more technological advantage than they lost in many other areas. This includes advanced materials, commercial aerospace, communications, computing/IT, energy, environmental, instrumentation, life science, military/defense, and pharmaceutical/ biotech. 

What regards R&D, academia has become the go-to organization for performing advanced basic research and even applied research when government or industrial organizations are looking for cost-effective ways to perform a development program. For many years now, academia has performed the majority of basic research as industrial organizations have reduced their involvement in basic research. The U.S. university and college systems continue to lead other countries in research, technology and innovation. For example, of the top 10 universities in the world, eight are in the U.S. (Harvard, Stanford, MIT, UC-Berkeley, Princeton, CalTech, Columbia and the Univ. of Chicago) and two are in the U.K. (Cambridge and Oxford). Of the top 20 universities in the world, 16 are in the U.S., with Switzerland’s ETH and Univ. College London being the non-U.S.-based standouts—the other top U.S. universities include Yale, UCLA, Cornell, UC- San Diego, Univ. of Washington, Univ. of Pennsylvania, Johns Hopkins and UC-San Francisco. This ranking system is run by the Center for World Class Universities at Shanghai Jiao Tong Univ., China. However, five of the top 10 in the Economic Intelligence Unit’s 2015 Global Talent Index are in Europe—Denmark, Finland, Norway, Sweden and Switzerland. The same countries as were in the top 10 for the 2011 version of the Index. The U.S. was number one in both versions of the Index. The Nordic region of Europe is noteworthy as it has four of the top countries in the talent index. The Nordic region as a whole has high government spending, as a percentage of GDP which is maintained throughout all stages of education, right through to universities, which explains why it has outperformed so many prominent rivals in the developed world in the overall index. The linguistic and technical skills of the Nordic countries’ working population are also particularly strong.

What concerns R&D staff, the researchers surveyed indicated that money is likely the most important component for maintaining and attracting researchers. Tied closely to creating a strong research staff is the creation of an innovation culture within the R&D organization.

R&D has been, still and will remain imperative for understanding and making the “best” of “our” lives on planet “earth”. Here comes three questions: first, how to assess the outcome and “how best is best”; second, which lives and which are those included in “our”; third, what are the impacts on “earth” and would the earth provide all the necessary ingredients at all times.  The attached file demonstrates that R&D around the world is still driven with less investments towards solving the threats facing the majority of world population. The focus as far as the majority of the world population is concerned is still geared towards one of the three main sustainability pillars which is “Economy”. The “environment” and “social” issues of the majority of the world population have to remain of much less priority.

Click to access 2016GlobalR%26DFundingForecast_2.pdf

The history of technology (https://en.m.wikipedia.org/wiki/History_of_technology) involves invention, development and implementation of techniques, skills, methods and solutions with consideration to the best available knowledge and know-how. In the evolution of technology it was shaped and reshape by using different forms of energy: man and animal power (muscle’s energy); energy from plants in (agriculture revolution); energy from simple natural resources (fossil-fuel era); and the advanced use of natural resources (nuclear power). The history of technological evolution thus describe transformations in life-styles and civilizations. Throughout these historical transformations, humans realized not only the importance of energy for life and survival but more importantly the limitations, threats and negative impacts embedded in the different forms of energy and associated interactions in the life-cycles of production and consumption. More recently, we came about the needs to be able to master all problems, threats, negative impacts and possibly even control the future using technology (https://en.m.wikipedia.org/wiki/Technology). This is the birth of sustainability and creation of green technologies with renewable and sustainable energy resources (https://en.m.wikipedia.org/wiki/Sustainable_energy) for the sake of protection and preservation of natural resources in particular aquatic, ecosystem and biodiversity, i.e. life and its quality on earth.

 In ecology, sustainability is the capacity to use our natural and essential resources for benefit of future generations as well (https://en.m.wikipedia.org/wiki/Sustainability). However, from the geological perspective and biological evolution viewpoint, the future of the Earth can be extrapolated based upon the estimated effects of several long-term influences. This is indeed, very complex and can only be predicted without great details (https://en.m.wikipedia.org/wiki/Future_of_the_Earth).

COOPERATION FOR SUSTAINABILITY is imperative to put the world on the right track for achieving the UN-SDG. It is about global transformation of all sector activities and on all levels for shaping and reshaping our lifestyle to protect and preserve all life forms on earth.
Textile industries (https://en.m.wikipedia.org/wiki/Textile_industry) are among main sectors that contribute in major production of pollution and waste that threaten global freshwater resources.

Freshwater on our planet is precious and without sustainable management of such vital resource all life forms on planet earth will sooner or later vanish. Sweden Textile Water Initative brings together Swedish leather and textile companies in collaboration to reduce water, energy and chemical use in their supply chains.

The Sweden Textile Water Initiative announces the global results for the financial year ending 31 December 2015. The environmental, social and financial (the basic pillars of sustainability) results have surpassed expectations. Results have been collected from the Initiative’s scaled up global programme to increase efficient water, energy and chemical use at factory level in India, China, Bangladesh, Turkey and Ethiopia.

Among the goals and objectives of the Sweden Textile Water Initiative “STWI” are creating guidelines for increased sustainability worldwide. Based on the assumption that common guidelines pave the way for real change, STWI-guidelines provide suppliers with clear instructions on how to work towards improved water efficiency, water pollution prevention and wastewater management in production processes. The guidelines are available in English and Chinese. Visit the Guidelines page to learn more: http://stwi.se, http://smallbusiness.chron.com/kinds-pollution-textile-factories-give-off-77282.html

Water is emerging more and more to be a global neccessity not only for the survival of life on planet Earth and improving our life quality on all scales and levels but also for providing young generation with meaningful jobs.

http://www.unwater.org/campaigns/world-water-day/en/
Sustain-earth.com continues to look far and deep in our future on planet Earth.

Where are we today in the process of promoting sustainability ( https://en.m.wikipedia.org/wiki/Sustainability). To know this we have to examine the existing situation. 

There are needs to know the diverse parameters and factors governing the outcome of our efforts in relations to the goals of the ongoing “sustainability mission” as defined by the UN-SDG (https://en.m.wikipedia.org/wiki/Sustainable_Development_Goals). It is essential to have wide-range of global observations, enough infra-structures of instruments and global alternative of approaches for measuring and assessing our achievement in managing the process and promotion of sustainability (https://en.m.wikipedia.org/wiki/Sustainable_management). We have just to apply the simple role “what we can not measure does not exist” also “what we can not measure we can not control”. 

There are many imperative questions in this context: how can we assess and measure sustainability? Do we have enough world-wide observation systems and tools? Are there enough appropriate instruments and approaches? Who is doing what, how and when? What are the spatio-temporal status of sustainability on regional and global scales? These questions and associated answers are not straightforward and far from being known everywhere, for everyone and whenever necessary for taking actions. So far, science, technology and R&D have not delivered sustainable answers for the addressed questions as if they did so, we did not need to be in the situation we have today and there is no warranty that they will do so in the future if we keep the addressed questions unanswered and keep going “business as usual”. 

What we know today is focused on replacing fossil-fuel with renewables, which is in itself a slow process and far from filling the complete width of managing sustainability. Associated with this is merely a single but imperative parameter (https://en.m.wikipedia.org/wiki/Parameter), i.e. the “changes in global average surface temperature” with complex system of observations upon which various models can predict essential and important data about climate and weather under the prevailing global warming conditions (http://www.globalissues.org/article/233/climate-change-and-global-warming-introduction).
Even if science, technology and R&D did what they are supposed to do to fully support and promote sustainability on the global scale still there are political, socio-environment and economic obligations for appropriate management of sustainability according to the outcome of the Paris Conference in December 2015 (https://en.m.wikipedia.org/wiki/2015_United_Nations_Climate_Change_Conference). It has already taken several decades to convince world politicians and policy-makers to recognise the threats from global warming though it was already known for many decades in science and technology circles. It is this time lag and slow communication between science, technology and R&D on the one hand and politics, socio-environment and economics on the other which causes severe threats for appropriate advances and successful implementation of the UN-SDG.

The outcome of the Paris Summit of 2015 (http://unfccc.int/meetings/paris_nov_2015/meeting/8926.php) is an alarming collective reminder of what we constantly failed to do to meet a growing number of global problems. Beneath global warming there is, indeed, an accelerating pile-up of complexity of old unsolved issues.

Historically, there have been three major global modifications for human settlement, migration and mobility on earth. These can even be decribed as tectonic transformations of our lifestyle, which have shaped and reshaped human life and affected human streams around the globe: agriculture, urbanization, and industrialization. These three can very well denote stages or phases of socio-economic developments without specific order though agriculture and food production are essential, central and common needs for us and will remain to be so. It is not strange that agriculture and food production were among the first activities for humans on earth, thereafter came industrialization and urbanization. However, science and technology were, and still are, natural prerequisites for any socio-economic development to take place anywhere. Implementation of innovations in science and technology is not straightforward, i.e. in the process of industrialization and urbanization, as it might seem in the first place. I do agree with Albert Einstein who is one of our great thinkers and philosophers of all times “The world we have made as a result of the level of thinking we have done thus far creates problems we cannot solve at the same level of thinking at which we created them.” 

Urbanization is a major effect of the expansion of industrialization, and both urbanization and industrialization are very much dependent on science, technology and education. Urbanization, however, unlike industrialization has different dynamics and evolution, and can be much more dependent on policy-making and management, at least in terms of socio-economic planning. Even though, the simple definition of urbanization, i.e. the process by which towns and cities are formed and become larger as more and more people begin living and working in central areas (http://www.merriam-webster.com/dictionary/urbanization), the full definition does involve the quality or the state or the process of becoming urbanized. Increasing urbanization is hardly a new phenomenon, this has been happening since the time of the first city, somewhere between 6,500 and 8,000 years ago. Urbanization was even associated with many glorious and famous civilization, e.g. in ancient Egypt that brought excellent examples of harmony, social and cultural developmemts. Among important new issues that make us to re-think and re-consider what urbanisation brought with it: are sustainability; the implementation of UN-SDG; the emerging needs for adaptation to the post fossil-fuel era and what urbanization should be in terms of preservation and protection of water, energy and natural resources.

Post-agricultural urbanization caused dramatic increase in population in cities and towns versus rural areas. A process that began during the industrial revolution, when workers moved towards manufacturing hubs in cities to obtain jobs in factories as agricultural jobs became less and less common. Urbanization in China, for example, has brought hundreds of millions of people from rural locations to the bustling coastal metropolises. The effects of urbanization, however, are more tangible and better recognized than those of agricultural land-use; e.g. air pollution and increasing child asthma; forced choice between rural hopelessness and urban despair; does urbanization creates a good living places for all citizens and people, particularly families; increased loads of sewage discharge into the streams. Above all, the severe expansion of slums within and around major/mega cities and towns.

Across the world, slums are home to a billion of people, one in seven of the world’s population. By 2050, according to the United Nations, there could be three billion. The slum is the filthy secret of the modern mega-city, the hidden achievement of 20 years of untrammelled market forces, greed, neglect and graft (http://www.newstatesman.com/global-issues/2011/08/slum-city-manila-gina-estero). Megacities will often turn into Megaslums under the coming and increasing urbanisation, fueled by migration and differential birthrates. We see this occurring first of all in parts of Africa, Asia, and Latin America. As current immigration trends continue, we will see the emergence of true Megaslums in Europe, North America, Oceania, and even in Japan and other presently low-migrant wealthy nations that are losing the demographic race (https://alfinnextlevel.wordpress.com/2015/10/23/urban-world-utopia-or-global-dysgenic-idiocracy/).

For older cities in developed countries – London, Paris or New York – urbanization took place gradually over a century and with tight interactions with industries and engagenment from  research, technology and education. They had time, resources, know-how and knowledge to adjust. In contrast, in developing Asian, intense urbanization is taking place within few short decades in random fashion and completely degenerated from supporting infra-structures and with complete absence of public and basic services, e.g. education, health, transport, water and sanitation. Unlike the Western cities that urbanized earlier, developing Asian cities simply do not have the administrative, management, institutional and financial capacities to manage urbanization and resulting socio-economic upheaval within such short periods. Urbanization is, indeed a complex challenge, with implications that are difficult to forecast especially in the absence of coordinated policies, management and administration (http://thediplomat.com). Most disastrous consequences arise with rapid and random urbanization in the developing countries (http://www.iied.org/study-warns-failure-plan-for-rapid-urbanisation-developing-nations). Governments in Africa and Asia must have strict plans for urbanization or risk harming the future prospects of hundreds of millions of their citizens with knock-on effects worldwide. They should heed lessons from Brazil whose failure in the past to plan for rapid urban growth exacerbated poverty and created new environmental problems and long-term costs that could have been avoided (http://knowledge.zurich.com/risk-interconnectivity/the-risks-of-rapid-urbanization-in-developing-countries/).

By 2050 more than two thirds of the world’s population will live in cities, while the many benefits of organized and efficient cities are well understood, we need to recognize that this rapid, often unplanned urbanization brings risks of profound social instability, risks to critical infrastructure, potential water crises and the potential for devastating spread of disease. These risks can only be further exacerbated as this unprecedented transition from rural to urban areas continues. The increased concentration of people, physical assets, infrastructure and economic activities mean that the risks materializing at the city level will have far greater potential to disrupt society than ever before (http://www.afdb.org/en/blogs/afdb-championing-inclusive-growth-across-africa/post/urbanization-in-africa-10143/). Urbanization in Africa has largely been translated into rising slum establishments, increasing poverty and inequality. However, there are large variations in the patterns of urbanization across African regions. The relatively fewer slums in North African countries is mainly attributed to better urban development strategies, including investment in infrastructure and in upgrading urban settlements. More broadly, 60% of African citizens live in places where water supplies and sanitation are inadequate. As most of the migrants from rural areas are uneducated/unskilled, they end up in informal sector with low income and intermittent, and naturally seek for shelters or become tenants of slum landlords. Many African cities have, therefore, to deal not only with slum proliferation but also with increasing insecurity and crime. Weak institutions have contributed to poor urban enforcement, resulting in dysfunctional land and housing markets, which in turn has caused mushrooming of informal settlements. Furthermore, African governments have neglected the key drivers of productivity which include small and medium-size enterprises, human resource and skills development, and technological innovation. These factors are essential in advancing predominantly informal, survivalist and basic trading activities to higher value-added work (http://www.un.org/apps/news/story.asp?NewsID=35556&Cr=URBAN&Cr1#.VtsxxUV86nM).

Relevant slideshare: https://www.slideshare.net/mobile/PECSweb/urbanization-brief-history-future-outlooks; https://www.slideshare.net/mobile/RajendraPSharma/urbanization-a-theoretical-view-perspectives-growth-cause-and-problems

Here is a short summary on How Slums Are The Fastest Growing “Lifestyle Communities”: http://www.theurbandeveloper.com/fastest-growing-suburbs-slums/

Please, note the forthcoming joint Symposia, Cairo, 3-5 May 2016, on Product Development Innovation “PDI”, and Industrial Systems and Operations Management “ISOM”, an outcome of EC-funded TEMPUS-collaboration (for 2014-2020 the new Erasmus+ aims to support actions in the fields of Education, Training, Youth and Sport with strong international cooperation dimension in the field of higher education http://eacea.ec.europe.eu/tempus) between universities in Germany, Italy, Sweden and Egypt. These Symposia are intended to fill the gaps in industrial engineering through bringing together industries and the academies including fostering networking, collaboration and joint efforts among the participants to identify major trends in Industrial Engineering today. For further information, please see 

(https://db.tt/AbfWfFJL; https://db.tt/TDrHYd7S; https://db.tt/xhig15Ui).
We look forward for joining us and being part of these interesting activities/
Dr. Farid El-Daoushy

Senior Professor, Dept. of Physics and Astronomy, Ångström Lab., Uppsala University

Education for Sustainable Development “ESD” or Sustainability Education (https://www.plymouth.ac.uk/your-university/sustainability/sustainability-education/esd) is about enabling every human being to acquire the knowledge, skills, attitudes and values necessary to shape a sustainable future. The Nordic countries have long traditions in meeting the needs for changing climates by being at high-latitudes where water change phase from being solid ice to liquid water. Also, where precipitation can be either snow or rain. The point here is the phase change of the water, as from the management point of view, has much technical requirements though the high abundance of water is a gift of nature to the Nordic countries. Though the temperatures at high-latitudes may have positive impacts on health, they are technically speaking not as friendly to live in as compared to lower latitudes. In terms of the sunshine and its seasonality the Nordic countries are not in same lucky situation as countries around the Mediterranean or even the equator. Another severe limitation for life at high-latitudes is temperature as the functioning and metabolism of life systems in particular for humans have their own conditions. The associated challenges in terms of water and energy, however, turned to be of great advantage for finding answers for confortable living for everyone where the baseline is long-term and large-scale survival. This is exactly the core of sustainability where its there pillars have to be in tact (economic, environment and social). To translate population challenges to individual solutions of complex problems under varying and shifting “economic, environment and social” conditions, instruments and tools for doing so have to be accessible and affordable for everyone but yet in communicative and structured manner. That is being defined in modern times as EDUCATION where its content, i.e. knowledge, is not static but now and then needs to be updated, structured or even improved. This dynamic part of education and knowledge “RESEARCH” is imperative and has to continuous and intensive. The world-wide recognition of sustainability as life-style promotes new global necessities in education and research. In this context, pedagogical issues at all stages and types of education and research have been recognized by being essential. 

The Handbook of Research on Pedagogical Innovations for Sustainable Development is the outcome of a major conference in Finland celebrating ten years of work promoting education, especially teacher education, for sustainable development or sustainability. “Reorientation of teacher education towards sustainability through theory and practice. Proceedings of the 10th international JTEFS/ BBCC conference Sustainable development, University of Eastern Finland Reports and Studies in Education, Humanities, and Theology No 7, University of Eastern Finland Joensuu, 2013. The work in this conference has been done in parallel with the UN Decade of Education for Sustainable Development (UN DESD: 2005– 2014). The Conference followed UNESCO’s rigorous and open definition of Education for Sustainable Development.

The main areas of discussion were: Sustainable early childhood education (ECE) and preschool education; towards systemic and integrative research methodology in ESD studies; pedagogy of sustainable future: museums, forests and culture environments as platforms for 21st century learning; sustainable education issues in science education; sustainable ICT in education; adult education for sustainable development, arts, design and skills; home, health and well-being, tourism research – connections on well-being, education and sustainability; teacher education for inclusion; social pedagogy as a dimen- sion of sustainable life; sustainability in community practices; and Earth Charter: values and multicultural approaches to education for sustainable development.

Uncovering the whys: what motivates teachers and researchers to conduct education and research in particular towards systemic and integrative methodology, application and promotion of Sustainable Developments is of major global interest.

https://www.dropbox.com/s/gpoz7bk60qh66tp/Teacher%20education%20and%20sustainability.pdf?dl=0

His Highness Sheikh Mohammed bin Rashid Al Maktoum, Vice-President and Prime Minister of the UAE and Ruler of Dubai, has launched the Dubai Clean Energy Strategy 2050, which aims to make Dubai a global centre of clean energy and green economy. 75% of the emirate’s energy will come from clean energy sources by 2050, thus establishing sustainable model in energy conservation to be exported to the whole world, and to support economic growth to protect the environment and natural resources and to foster coming generations for a more sustainable future. In this context, Dubai will become the city with the least carbon footprint in the world by 2050 with sustainable economic sectors based on non-renewable energy resources and are unaffected by volatile energy prices.

International companies and R&D centres are called upon to make Dubai a base for testing and applying the next generation of clean energy technologies to create a global model that can benefit the world. 

The launched strategy has ambitious goals and consists of five main clear pillars: Infrastructure, legislation, funding, building capacities and skills, environment friendly energy mix.

The infrastructure pillar includes building a Solar Park for generation of the largest solar energy in the world from a single location with a capacity  of 5,000 MW by 2030. The second pillar is establishment of a legislative structure supporting clean energy policies in two phases. Dubai Green Fund, i.e. the third pillar is related to financing solutions for investment in research and development on clean energy and its application. The fourth pillar aims to build human resources capabilities through global training programmes in the field of clean energy in cooperation with international organisations and institutes. The fifth pillar is focused on creating an environment friendly energy mix comprising solar energy, nuclear power, clean coal and gas.

http://www.emirates247.com/news/emirates/mohammed-launches-dh50bn-dubai-clean-energy-strategy-2015-11-29-1.612173

There are contradictory predictions about the fate of Dubai by 2100, i.e. uninhabitable or the center of the world. The temperature increase due to global warming can render life in the MENA region almost uninhabitable (http://edition.cnn.com/2015/10/27/world/persian-gulf-heat-climate-change/; http://www.kippreport.com/fcs/abu-dhabi-dubai-and-doha-uninhabitable-by-2100/; 

http://m.mic.com/articles/127458/scientists-say-climate-change-could-render-the-middle-east-almost-uninhabitable-by-2100#.wYEmPYmaU).

However, the population dynamics which is predicted to decrease in the Americas and Europe and to increase in the Asia and Africa. This will make Dubai to be the center of the world instead of London which is currently holds this status (http://gulfelitemag.com/dubai-set-become-centre-world-year-2100/; http://m.khaleejtimes.com/nation/general/dubai-to-be-centre-of-the-world-by-2100; http://m.arabianbusiness.com/dubai-set-become-the-centre-of-world-by-2100-gov-t-expert-predicts-581660.html).
  

BI-Science YouTube is a Business Intelligent solution provider, for the on-line media industry, of videos about the newest discoveries in space, medicine, and biotech along with science explainers (https://www.youtube.com/channel/UC9uD-W5zQHQuAVT2GdcLCvg). 

This video by BI Science is about one of the many irreversible effects of climate change. Sea levels have been rising at a greater rate year after year, and the Intergovernmental Panel on Climate Change estimates they could rise by another meter or more by the end of this century. In 2013 National Geographic showed also that sea levels would rise by 216 feet if all the land ice on the planet were to melt. This would dramatically reshape the continents and drown many of the world’s major cities.

Sea level rise is caused by two factors related to global warming: the added water from melting land ice and the expansion of sea water as it warms. The increase in sea level is being measured by two methods, i.e. tide-gauges and satelite altimetry (http://www.global-greenhouse-warming.com/measuring-sea-level.html). Many leading science and technology institutes and organisations have reported on the increase of sea level which is estimated to be up to or even more than 3.39 mm/yr depending on the used approached, e.g. https://www.skepticalscience.com/sea-level-rise.htm; https://www.ipcc.ch/publications_and_data/ar4/wg1/en/spmsspm-direct-observations.html; https://www.ipcc.ch/publications_and_data/ar4/wg1/en/ch5s5-5-2.html; http://climate.nasa.gov/vital-signs/sea-level/; https://www.ipcc.ch/publications_and_data/ar4/wg1/en/faq-5-1-figure-1.html

Here are some inconvenient facts about the global impacts of the rise in sea level on heavily populated coastal regions (https://m.youtube.com/watch?v=VbiRNT_gWUQ).

How to make our cities sustainable, indeed there is no “one-size fits all” solution as cities around the world face different challenges when it comes to defining what a sustainable city is. Joinig the ongoing transformation to a more sustainable future is becoming not only a global need but rather a neccessity where the urbanization process is not a random process anymore. Yet, the historical, cultural and traditional evolution will play cental role for adoptation along with many other indicators across socio-cultural, economic, climate, energy and environmental domains. ” Juliet Davis, senior lecturer in architecture at Cardiff University says “there will be no one size fits all”. Lucy Warin, project manager at Future Cities Catapult says “There are of course underlying principles that support good, sustainable urbanism – firstly, good city governance, powerful city leaders who know their region and can respond quickly as issues arise. And secondly, citizen engagement. Smart people make smart cities and any sustainability solution should start and finish with the citizens”.

More on how to make our cities sustainable at:
http://www.theguardian.com/sustainable-business/2015/apr/17/how-to-make-our-cities-more-sustainable-expert-view?CMP=Share_iOSApp_Other

Here are, also, some quirky ideas for making our cities more sustainable:

http://www.theguardian.com/sustainable-business/2015/apr/16/ten-quirky-ideas-for-making-our-cities-more-sustainable

This said, there are other important issues, what regards the global transformation to a more sustainable future, to take in consideration. Though about 70% of the global population is expected to live in cities by 2050, there very little known about how we can achieve sustainable rural-urban integration. This is specially true in developing counting where for example 70% of the African population is living in rural region with agriculture as a main source of income and employment. Rural Africa suffers from extreme levels of poverty in terms of energy, water and sanitation along with general lack of basic public services and infrastructures for education, health, transportation and communication.

Many regions worldwide are facing new and major challenges for generations to come. The world is currently, going through tectonic transformations for meeting the UN-SDG (Paris meeting, 2015) and adapting more sustainable life-styles to meet the future realities of the post fossil-fuel era. With growing population, declining natural resources and increasing waste and pollution and uncertain climate and energy pressures, it becomes imperative to have careful large-scale and long-term planning and manageable policies. To meet the expected doubling of population in Uppsala county a Climate and Energy Strategy is being worked out with consideration to all development areas identified in the regional development plan. In this context, Uppsala county is planning to be an international centre of excellence in the climate-Energy area. 

See how one of the most explosive Swedish regions in terms of population and socio-economic developments is planning to cope with the complex challenges of its distant future.

Click to access strategy-short-version.pdf

Energy and mass are conserved in closed systems. Looking at our universe, the solar system, the earth and using the concept of closed systems we find the following. Since the earth can be looked upon as a “closed system” then we can conclude that what we consume in terms of any fossil natural resources, i.e. being mined and used, is irreversible and can not be brought back as they were before. The same can be also said about natural minerals. Furthermore, all irreversable processes (mining and associated production to other forms, e.g. energy and industrial products) generally give rise to irreversible hazardous products in form of waste and pollution that impacts negatively on the functioning of natural systems. These natural systems, e.g. aquatic systems and land-water resources are generally expected to go out of order and to suffer from “malfunctioning”. In this context the earth’s natural resources can be generally classified into four main categories: 

(1) Mined and used irreversibly with major and remarkable large-scale and long-term damaging effects and negative environmental impacts 

(2) Mined and can be used reversibly but with high economic costs and major side-effects and negative environmental impacts

(3) Mined and can be used reversibly with minor economic costs and limited negative environmental impacts

(4) used and reused reversibly with limited environmental impacts

The International Renewable Energy Agency published an interesting report on the global Renewable Energy benefits “The Economics of Renewables”. This is the added-value of the decarbonization of energy for mitigating the global warming.  

https://www.dropbox.com/s/12cy7ynt4sgwzwk/IRENA_Measuring-the-Economics_2016.pdf?dl=0

  


The world around us is moving steadily  and rapidly towards different distinations to meet the growing challenges for post oil and fossil-fuel era or even more seriously stated towards what we can call the post natural resources era. One exception is the solar energy which will outdate all other natural resources on earth including water and the life itself. 

This does come with a surprise as all existing knowledge and research predictions indicate that all natural resources on planet earth are, or sooner or later will be, going through peak-consumption followed by gradual decline and even annihilation. In the case of water and life it is about peak-quality and peak-life as we are also facing peak-waste and peak-pollution in this very century. However, it is only our collective human intelligence, integrated worldwide innovation and coherent hardwork combined with systematic planning and above all sustainable policies and management strategies that can save our planet from total collapse and annihilation. 

Successful transformation to sustainable future for planet Earth can not and will not be achieved without effective global dialog, shared knowledge and expertise combined with worldwide solutions and work for implementation of innovative and sustainable policies and management strategies. We can not imagine that this can be achieved by “business as usual” where only a small and localized portion of the world population has access to knowledge and expertise while the large majority of the global population lack the resources and capabilities to contribute constructively in saving planet Earth. 

It is not about finding false and destructive solutions for erasing poverty (only filling the hungry stomachs) since we will be overloading planet Earth with more blind consumption, generating and accumulating enormous waste and pollution everywhere. It is about empowering the majority of the world population with resources and capabilities to actively share the heavy responsibility for preservation and protection of our collective natural resources on earth. This is only possible if we have collective vision and mission for more sustainable future for our planet Earth. 

It is interesting to see how some first-class universities (http://ocw.mit.edu/index.htm) are taking major steps for the globalization of knowledge and increasing the mobility of expertise around the world.

The post industrial revolution era was  geared to lifestyle based on production and consumption engineering technology. While our global lifestyle is moving on new tracks to revert what went wrong in the post industrial era new concepts are being emerging. Future  technology will involve the expansion of the so-called “Reversed Engineering” where 12 GREEN Engineering Principles would be absolutely imperative for getting our planet on large-scale and long-term sustainability roads. 

Read more about this: http://pubs.acs.org/doi/pdf/10.1021/es032373g

Transformations to sustainable societies involve seeing the big picture to achieve optimization in all sectors and on all levels, i.e. for the benefit of everyone. An example is provided here, INDUSTRIAL AND OPERATIONS MANAGEMENT. 

http://learningcourses.com.sg/dt_courses/diploma-industrial-operations-management-rp/
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