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

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.

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

Water management explained simply means “water care” where water is being cleaned after using it and before injected it again to the environment. Water in nature is meant to be clean and fresh, and that is the way water ends it global natural cycle in the form of rain. 

Successful water management policies are not only essential for life on earth but it is imperative and should be composed of many dynamic key issues involving the effective removal of waste and pollution from joining the water cycle in all its stages. Waste and pollution management, public awareness, education, protection of water bodies and associated monitoring programs are typically carried out through major, strict and comprehensive national strategies, directives and regulations. These have to be in place all the time, anytime and everywhere, it is not a matter of being done now and then as the costs involved in rehabilitation are very huge and time consuming with complicated procedures and actions.

A typical case to illustrate is The Citarum River, indonesia, which is known as the dirtiest river in the world. The Roadmap for the rehabilitation of the river system is an extensive plan with many components and phases that is to be completed by 2023 at a total cost of $3.5 billion. This will be a huge undertaking by people and government of Indonesia for empowering communities to better plan and manage their water resources for a more sustainable future.

https://haltonrecycles.wordpress.com/2012/10/10/the-importance-of-waste-management-and-fresh-water-resources-looking-at-indonesias-citarum-river/
  

WWW is without hesitation a historical invention that changed and still changing the fate of all humans anywhere, at anytime and in every nanosecond on planet Earth. Information Communication Technology “ICT” is moving faster and faster to involve more and more active coupling of humans and machines.

With the birth of World Wide Web “WWW” in May 1993 new generations from 1990 and beyond are now shaping out planet and our lives. The Internet seems like it has always been around and with us …. isn’t it? In this short two decades, or so, is has affected us and changed our lives far more than anything else in the whole intergrated human history with no similar parallels. The question is what this ICT-revolution will take us to and what would the world be like in say 2020 and beyond (https://ispanico82.wordpress.com/2013/05/22/happy-birthdat-www/)

The fast global progress in ICT within the vast landscape of WWW has benefited enormously from all previous stages of developments. Future possibilities are very huge with increasing degree of digital and wireless communication, combined sences, embodied interactions and with computer technology that took us from central computer and many users in early 1940s to smart cities in 2020. We are heading more and more towards smarter solutions, e.g. smart homes, smart factories, smart space, smart classrooms, smart shops, and much much more. ICT for the rich, the poor, the young, the old, and furthermore between communications between humans over the whole globe, humans and machines, and machines and machines: http://www.ourcommonfuture.de/fileadmin/user_upload/dateien/Reden/wahlster_opening.pdf

Policy-makers in Europe and the U.S. have addressed major concerns about the failure of integration of immigrants brought into their labor-markets after the rapid industrial and technology transfer post WWII, e.g. for more information visit the following websites (http://ec.europa.eu/dgs/home-affairs/e-library/documents/policies/legal-migration/general/docs/final_report_on_using_eu_indicators_of_immigrant_integration_june_2013_en.pdf) and (http://m.immigrationpolicy.org/?url=http%3A%2F%2Fwww.immigrationpolicy.org%2Fissues%2Fcitizenship&utm_referrer=https%3A%2F%2Fwww.google.se%2F#2887).

With these experiences in mind and the fact that Europe and the U.S. passed through a wide-scale of urbanization and modernization especially after WWII, we can already expect similar negative consequences and impacts in the developing countries because of the ongoing fast urbanization, in particular Africa. With the exception that the negative consequences and impacts in Europe and the U.S. were/are relatively very much smaller than the observed trends and the expected future changes in the developing countries. Currently, there is already gradual and intensive internal migration due to the enormous urbanization process that is taking place in many developing countries around the world. This process is certainly resulting from the severe failure of integration of rural and urban regions and the core reason for the expansion of poor communities around major/mega cities. This indeed, has two major future impacts: (1) gradual degradation of the basic public and private infra-structures of newly urbanized regions; and (2) shortage of the relatively experienced local and native labor in rural regions on many levels in general and collapse of the agriculture, in particular, with associated negative impacts on food and agro-industries.

This is a very ignored issue in Africa though many severe impacts are already observed in big and mega cities in Africa, e.g. Cairo, Lagos, Nairobi, Bamako……

IMMIgration is an integral part of human experience and always existed throughout human history. In a dynamic world of continuous changes and unlimited needs for successful globalization IMMIgration would always exist. However, the motivations, dynamics and mechanisms are never the same. In this context, there are many critical questions that need to be answered not only at individual levels but also on the larger socio-economic landscape.

Shortly after WW-II immigration was very popular, and people and countries around the world benefited from the unlimited needs and diverse market possibilities that existed at that time. However, the current global situation what regards IMMIgration and INTEgtation is very much different than what it used to be after WW-II. Why the INTEgration of IMMIgarnts did not take a sustainable path, as it was wished, is among most important global political and socio-economic issues (http://ec.europa.eu/dgs/home-affairs/e-library/documents/policies/legal-migration/general/docs/final_report_on_using_eu_indicators_of_immigrant_integration_june_2013_en.pdf).

Full integration of immigrants in the U.S. is still an issue and most immigrants want to be Americans and fully participate in social and civic life. We can expect naturalization and integration programs to be an important part of comprehensive immigration reform. Immigrant integration has benefits for everyone because it enables immigrants to realize their full potential, contribute more in economy and develop deeper community ties. While the United States encourages legal permanent residents to become citizens, there is no national strategy for facilitating integration with sufficient infrastructures to smooth transition from immigrant to citizen. Failure to address this problem in the context of comprehensive immigration reform could lead to endless delays for the millions who currently seek services from USCIS and the millions more who will become part of the applicant pool following legalization.

Another important issue is the internal migration in many countries due the enormous urbanization process that is currently taking place around the world. This process is certainly resulting from the severe failure of integration of rural and urban regions and the core reason for the expansion of poor communities around major/mega cities. This indeed, has two major impacts: (1) gradual degradation of the basic public and private infra-structures of urbanized regions; and (2) shortage of labor in rural regions on many levels in general and collapse of the agriculture, in particular, with associated negative impacts on food and agro-industries.

http://m.immigrationpolicy.org/?url=http%3A%2F%2Fwww.immigrationpolicy.org%2Fissues%2Fcitizenship&utm_referrer=https%3A%2F%2Fwww.google.se%2F#2887

We leaned in our daily life experiences that “no fire without smoke”. Indeed, many of us started to lose confidence in food quality and have observed on many occasions disappointing situations. That doesn’t come without reasons or surprises as we are already familiar about many environmental abuses on several levels. In additions to this, violations of rules and quality guide-lines are existing worldwide as economic terms in production and services have sometimes higher priorities than quality standards. 

Here are some few examples why our food quality can be questioned. I personally have experienced number of violations even in best shops in Europe (in this case very few) where bread and cheese can be suspected for exposure to rat droppings, see for example (http://www.raising-happy-chickens.com/rat-droppings.html). 

In developing countries sanitation and poor water quality can pose additional threats in food production as the risk of exposure of food to insets and certain dwelling animals, e.g. rats,  can be high. 

Here are some warnings about existing problems in processed food even through legally accepted quality guide-lines (http://youtu.be/T75ULFUgEPk).

In all human civilizations building and constructions were central components in human life with continuous struggle for sustainable comfort living in harmony with nature. As the concept of sustainability did not exist in the same way as we know it today, ancient solutions were based on practical use of naturally available materials in combination with the sun as source of heat and thermal energy. Climate/weather conditions played major rules in building and construction and people adapted living to their environment.

The Egyptian Pyramids, temples and living rooms were built more than 4500 years ago with zero energy consumption, zero carbon dioxide emissions and no toxic waste. How the Pyramids and those buildings were built is still matter of speculation and debate. According to historical data ancient Egyptians built the Giza Pyramids; Khufu, Khafre and Menkaure in a span of 85 years in the 26th century BC. How such sustainable technology was mastered is still a mystery what regards saving energy, water and environment.
Most of current problems today are related to implementation and use of technologies whether or not suitable for the environments. Because of this, the conform of modern technology comes with very high price in terms of economy, environment and above all an enormous loss of cultural and locally based building codes that developed throughout several generations. Only, in few cases where enough resources and investments exist there are successful examples, however it remains to see how such solution can be expanded on larger scales. The “world’s first carbon neutral zero-waste city” is slowly becoming a reality of epic proportions. The prototypical sustainable city, Masdar, is currently under construction twenty miles outside of Abu Dhabi. When finished, the city will be powered entirely by renewable energy, making it one of the world’s most sustainable urban developments. The city has its own sustainability-driven research center, which is devoted to the development of alternative energy (http://youtu.be/FyghLnbp20U).

Among most recent advances in building material is a new type of cement that is based on Pozzolan, which can be found in nature from volcanic deposits. Also, industrial waste from iron and power plans can be recycled and used in producing green cement. Green cements, as compared to OPC “ordinary Portland cement”, are very energy and water saving, environmentally much more friendly with no waste remains and no emissions of GHG. Also, have enormous advantages especially what regards production cost, mechanical properties, duration and maintainance. Modern technology can produce sustainable building materials, green cement, for erection of complicated structures that have excellent durability but in much much faster time as compared to ancient civilizations. Currently, the best possible sustainable building materials can bring about energy saving of more that 90% with very near zero carbon dioxide emission and zero waste remains.

To understand the importance of Pozzolan in modern technologies for production of green cement one has to back 2000 years ago. The Romans at that time started making concrete but it wasn’t quite like today’s concrete. They had a different formula that resulted in not as strong as our modern concrete. Yet structures like the Pantheon and the Colosseum have survived for centuries, often with little to no maintenance. Geologists, archaeologists and engineers have arrived a key component in the Roman’s concrete: volcanic ash. Usually,  three parts volcanic ash were mixed to one part lime, according to Vitruvius, first-century B.C. architect and engineer. Modern research shows that the very secret of durability of the buildings of the Roman Empire was due to the chemical composition of concretes made with Pozzolan, i.e. the ash’s unique mix of minerals appears to have helped concrete to withstand chemical decay and damage. For information (http://www.smithsonianmag.com/history/the-secrets-of-ancient-romes-buildings-234992/).

In all human civilizations building and constructions were central components in human life with continuous struggle for sustainable comfort living in harmony with nature. We give here only some few examples. As the concept of sustainability did not exist in the same way as we know it today, ancient solutions were based on practical use of naturally available materials in combination with the sun as source of heat, the wind as source of mechanical and thermal energy. Climate/weather conditions played major rules in building and construction and people adapted their living to the environment.

The Egyptian Pyramids, temples and living rooms were built more than 4500 years ago with zero energy consumption, zero carbon dioxide emissions and no toxic waste. How the Pyramids and those buildings were built is still matter of speculation and debate. According to historical data ancient Egyptians built the Giza Pyramids; Khufu, Khafre and Menkaure in a span of 85 years in the 26th century BC. How such sustainable technology was mastered is still a mystery what regards saving energy, water and environment.

Traditionally other cultures have always adapted sustainable and eco-friendly methods, e.g. Indian architecture, designing and planning, in constructions. Living in harmony with nature has been an integral part of Indian culture, e.g. what regards waste disposal, light and temperature control, use of local materials, kitchen gardens and low carbon print.

Environmentally conscious buildings have been around for much longer than the public debut of our modern environmental crisis. Since the early 19th century, residents of Yazd, Iran, have been using wind as an alternative energy source to cool their homes on warm summer days. A ‘windcatcher’ is an ancient Persian architectural element used in various central and southeastern towns and cities in Iran, where the majority of the ecological fabric are made up of deserts. In deserts, the temperature varies greatly between day and night, with windcatchers becoming essential for keeping homes at a consistently comfortable temperature. Also, for the region located in northeast Iran at the foot of Mount Sahand, the mound-like homes are carved from volcanic rock, meaning that most of the materials needed to construct them were already located on site. Technically, the dwellings aren’t true underground homes since a portion of them sits above ground, but since much of the living space is buried, inhabitants can expect cooler temperatures during the day without having to jack up the air conditioning (and saving a lot of energy). Similar volcanic structures with carved homes/villages exist also in Turkey.

In certain parts of the world, wood was always a popular building material, e.g. in Scadinavia. Yet the use of wood is seldom seen amongst the modern or classic constructions. Due to a series of destructive fires in the 15th century, the use of timber as an architectural material was banned for sometime. Danish non-profit organization Realdania Byg commissioned Vandkunsten architecture studio to design a holiday house that combines the most up-to-date construction techniques with local traditional materials. The architects designed and built a traditional house clad in seaweed—a material that was once used in hundreds of homes on then Danish island of Læsø, of which only 20 remain today.

Most of current problems today is that people implement and use technologies whether or not suitable for their environments. Because of this the conform of modern technology comes with very high price in terms of economy, environment and above the enormous loss of cultural and locally based building codes that developed throughout several generations. Only, in few cases where enough resources and investments exist there are successful examples, however it remains to see how such solutions can be expanded on larger scales. The “world’s first carbon neutral zero-waste city” is slowly becoming a reality of epic proportions. The prototypical sustainable city, Masdar, is currently under construction twenty miles outside of Abu Dhabi. When finished, the city will be powered entirely by renewable energy, making it one of the world’s most sustainable urban developments. The city has its own sustainability-driven research center, which is devoted to the development of alternative energy (http://youtu.be/FyghLnbp20U).

Among most recent advances in building material is a new type of cement that is based on Pozzolan, which can be found in nature from volcanic deposits. Also, industrial waste from iron and power plans can be recycled and used in producing green cement. Green cements, as compared to OPC “ordinary Portland cement”, are very energy and water saving, environmentally much more friendly with no waste remains and no emissions of GHG. Also, have enormous advantages especially what regards production cost, mechanical properties, duration and maintainance. Modern technology can produce sustainable building materials for erection of complicated structures that have excellent durability but in much much faster time as compared to ancient civilizations. Currently, the best possible sustainable building materials can bring about energy saving of more that 90% with very near zero carbon dioxide emission and zero waste remians.

Additional new comers in green cement era is effective production and construction through automation and 3D Printing technologies (http://inhabitat.com/3d-printed-quake-column-draws-on-ancient-incan-building-techniques-to-withstand-earthquakes/). Architecture is tapping into 3D printing technology in a major way through the production of building elements and structural components. Recent developments have also begun to work on creating seismically resistant structures. California-based architecture firm Emerging Objects has developed a design called the Quake Column, which draws on the ancient Incan building technique known as “ashlar” and merges it with modern technology.

GCC countries (Gulf Cooperation Council) are moving faster to SuperGreen solutions in building and construction projects.

Dubai Electricity and Water Authority (DEWA) and the Emirates Green Building Council are strengthening cooperation for supporting a green economy in Dubai and the sustainable development of the Emirate. All future trends support the Green Economy for Sustainable Development initiative, launched by HH Sheikh Mohammed bin Rashid Al Maktoum, Vice President and Prime Minister of the UAE and Ruler of Dubai.

Follow the news:

http://www.albawaba.com/print/business/pr/dewa-and-emirates-green-building-council-discuss-promoting-green-economy-695944

With increasing worldwide population and predictions that 75% of the world population will be living in cities by the year 2050, building towards the sky can be unavoidable necessity. That would require more durable constructions and materials with appropriate building and architecture solutions. Future  Cities would require management policies with balanced policies consumption/waste versus protection/conservation of nature in accepted social context. Http://sustain-earth.com

Among the consequences of economy driven policies in ASEAN countries is the increasing economic gaps between countries in the region. For sustainable large-scale and long-term socio-economic developments it is vital to promote less developed countries as well. Shift from commercially driven agriculture to new technologies where the regional natural resources are not only used sufficiently but, also, sustainably managed in a manner that respect traditional systems of the rural areas. 

Commercialization always has some draw-backs as well, e.g. depletion soil fertility, and excessive use of chemical fertilizer, herbicides and pesticides with long-term impacts and threats on ecosystems in different ways. Strategies need to be implemented to create sustainable and profitable farming systems that realize the existence of vital rural societies in tact with the natural functioning and metabolism of natural eco-systems and in harmony with existing biodiversity.
https://www.jircas.affrc.go.jp/english/program/proC_1.html

Sustainability has been part of the human awareness since the birth of the ancient man on planet Earth. The instinct for survival and wellbeing has never been crystallized in well-structured components for building up webs of instrumental coordinated solutions until the 1980s with the introduction of the most widely quoted and used definition of sustainability. An imperative and collective need put forward by the Brundtland Commission of the United Nations in 1987: “sustainable development is development that meets the needs of the present without compromising the ability of future generations to meet their own needs.” 

The Earth is a unique planet in our universe with complex functioning structure of systems that support the evolution of complex webs of metabolic processes for sustaining all living forms on Earth.

 The man has always struggled for his survival on earth and in particular to get access to and to secure affordable food resources not only for himself but for the new comers as well.

After and during the industrial revolutions, the focus of humans was directed mostly on technical issues to free mankind from manual work, to find resources and technology for  basic necessities through mechanical and machinery work. The Man realized the role of science and technology for his wellbeing and since the nineteen and twenty centuries the advances in science and technology emerged more and more to be the only inevitable route for improving the living conditions. This didn’t come for free and price and costs for humans started to be huge with clear finger-print on the accelerating divergence of the three basic drivering wheels of sustainability: economy, environment and social drivers. 

Economic interests resulted in increasing consumption of natural resources with severe impacts on degradation of the environment because of increasing waste and pollution, and piling up of social defects in particular the remarkable failure in erasing global poverty. These along with enormous indicators of the declining natural resources as being defined by the so-called resource “peaks”.
 

The divergence and fragmentation of these drivers and spheres brought considerable, and yet, accelerating threat for the survival of humans.  The net result of what humans achieved in science, technology, policies and politics were in direct conflict with not only the search for wellbeing but also the very basic needs for survival.

The major spheres of the functioning and metabolism of all life forms on earth were  brought out of their natural equilibrium, e.g. the atmosphere with an increasing temperature because of global warming.

Global warming and accelerating production of waste and pollution have caused enormous damage on the hydrophere with irreversible effects on the ecological resources where humans are dependent on, e.g. fish.

The growing human population still induces additional challenges for achieving the goals for global sustainability developments.

The era of sustainable developments has already started but it is still in its infancy and the needs of the necessary knowledge are enormous in particular what regards building the underlying science and technology as well as the associated management policies in all sectors and on all levels.

For more information on sustainability visit: http://en.m.wikipedia.org/wiki/Sustainability

Http://sustain-earth.com” is an integrated coherent platform for Applied sustainability. Interests and efforts put by its coordinator and manager of started already through a simple experiment at the age of fourteen. As a young student, at Abo-Tyg/Assiut secondary school, starting to learn chemistry I bought a small amount of hydrochloric acid from my pocket money. I added the acid to a soil sample from the garden, it was a violent reaction in the test tube with evolution of gases. An exciting experiment where drew my attention with the conclusion that there must be geochemical reactions taking place in the environment. This in addition to continuous observations from summer holidays that I spent at the village of my grandfather, Cairo’s Waraa. Some local industries, farmers and poor people of the village, as is the case for many other villages on the Nile, used or you may say “abused” the water of the Nile to do their household needs, e.g. cleaning, washing animal and the removal of waste in general. These events and my experience of the continuous lack of water in the very arid environments prevailing in southern parts of Egypt as it rains one per decade etched an enormous early interest that caused gearing my early geology, chemistry and physics university education towards research on environmental waste, pollution and their impacts on global aquatic systems.

This resulted in an academic career in Environmental Physics a discipline that I created myself with further created further work in Applied Sustainability.

Water and nutrients are essentials for the evolution and sustainability of life on earth. The magic, secrets and drivers of life on earth are not human inventions. Human innovation is merely restricted to accelerating the natural metabolic processes on earth, e.g. production of food in agriculture, animal husbandry and fisheries, beyond natural rates and limits. The growing global population and the underlying industrial and economic systems continue to fuel the so-called human innovation towards a never ending spiral for more and more unsustainable consumption of the natural resources.

Humans can not servive on earth without clean water, healthy environment and sustainable food production. However, these requirements can only be fulfilled through sustained production and consumption of energy and natural resources for supporting the basic needs for humans, e.g. housing, education, health, transport and communication. What originally started for the benefits of human developments turned out to major threats for human survival because of increasing waste and pollution from use and abuse of the natural resources.
Humans have interfered in the natural functioning and metabolism of all life forms on earth with negative impacts on essential and global biogeochemical cycles. Examples are: global warming as resulted from malfunctioning of the global carbon-cycle. Degradation in O-cycle (oxygen cycle) is also remarkable because of unfit and polluted air in urbanized living areas, in particular cities as result of expansion of traffic and transport systems and random industrial activities; poor access to oxygen in aquatic systems because of eutrophication in aquatic systems and excessive use of fertilizers on land; enhanced photo-reactions in the atmosphere with the associated negative impacts of tropospheric production of ozone.

Declining reserves of natural phosphorous, are among emerging threats, because of increasing production and use of this limited natural resource with irreversible impacts on P-cycle. Agricultural and industrial nitrogen inputs to the environment currently exceed inputs from natural N fixation. The impacts of anthropogenic N-inputs have significantly altered the global N-cycle over the past century. Global atmospheric N₂O have increased from pre-industrial levels where most of which are due to the agricultural sector.

Human activities have major effects on the global S-cycle. The burning of coal, natural gas and other fossil fuels has greatly increased the amounts of sulphur in the atmosphere,?ocean and depleted the sedimentary rock sink, i.e. instead of being burned at steadily rates. Over most polluted areas there has been a 30-fold increase in sulfate deposition. The enhanced sulphur and nitrogen oxides in the atmosphere is causing negative impacts through acidification of aquatic systems with global negative feedback effects on aquatic life and vegetation.

All in all quality of global land-water resources are under accelerating threats from pollution  and waste.

http://www.flatheadwatershed.org/natural_history/natcycles.shtml