Sustainable Technology of 2520

Sustainable Technology of 2520 ?

Predicting the exact nature of sustainable technology in 2520 is a fascinating thought experiment. However, based on current trends and knowledge, here are some potential areas of development:

1. Advanced Energy Solutions:

• Fusion Power: If achieved, fusion would provide a clean, abundant energy source.  
• Space-Based Solar: Harnessing solar energy from space and beaming it to Earth could provide a continuous, inexhaustible supply.  
• Energy Storage: Highly efficient, compact energy storage solutions would be crucial for balancing energy supply and demand.

2. Resource Management:

• Circular Economy: Advanced recycling and resource recovery technologies would minimize waste and maximize resource utilization.  
• 3D Printing with Recycled Materials: On-demand manufacturing using recycled materials could reduce the need for resource extraction.
• Precision Agriculture: Technologies that optimize resource use in agriculture, such as AI-powered irrigation and fertilization, could help feed a growing population sustainably.  

3. Environmental Remediation:

• Carbon Capture and Storage: Advanced technologies to capture and store or utilize carbon dioxide from the atmosphere could help mitigate climate change.  
• Ocean Cleanup: Large-scale systems to remove plastic and other pollutants from the oceans could help restore marine ecosystems.
• Ecosystem Restoration: Technologies to restore damaged ecosystems, such as forests and wetlands, could help enhance biodiversity and ecosystem services.

4. Sustainable Infrastructure:

• Smart Cities: AI-powered systems could optimize energy use, transportation, and waste management in urban areas.  
• Green Buildings: Buildings that generate their own energy, use sustainable materials, and minimize environmental impact could become the norm.
• Sustainable Transportation: Advanced electric vehicles, high-speed rail, and other forms of sustainable transportation could reduce reliance on fossil fuels.

5. Biotechnology:

• Biomanufacturing: Using biological systems to produce materials and products could reduce reliance on fossil fuels and create more sustainable manufacturing processes.  
• Genetic Engineering: Advanced genetic engineering could help develop crops that are more resilient to climate change and require fewer resources.  

6. Information Technology:

• AI for Sustainability: AI could be used to optimize energy use, manage resources, and monitor environmental conditions.  
• Cloud Computing: Cloud computing could reduce the need for physical infrastructure and promote resource sharing.  

It is important to note that these are just a few possibilities. The actual nature of sustainable technology in 2520 will depend on a variety of factors, including scientific advancements, economic conditions, and social priorities.

Additionally, it is crucial to consider the ethical and social implications of these technologies. It is important to ensure that sustainable technologies are developed and used in a way that benefits all of humanity and does not exacerbate existing inequalities.

What is Sustainable Technology of 2520 ?

While it’s impossible to know for sure, here’s a breakdown of what sustainable technology in 2520 might entail, based on current trends and logical extrapolations:

Core Principles:

• Radical Efficiency: Technologies will likely operate at near-perfect efficiency, minimizing waste and maximizing output with minimal resource input.
• Closed-Loop Systems: Resources will be perpetually cycled, with waste becoming a resource for other processes. Linear “take-make-dispose” models will be obsolete.
• Harmony with Nature: Technologies will be designed to mimic and integrate with natural systems, minimizing disruption and even enhancing ecosystem health.
• Decentralization: Energy, resource production, and even manufacturing may be highly localized, reducing reliance on massive centralized systems.

Specific Technologies:

• Energy:
  • Fusion Power: Likely a dominant energy source, providing clean and abundant power.
  • Space-Based Solar: Large-scale solar farms in orbit, beaming energy to Earth.  
  • Ambient Energy Harvesting: Devices that capture energy from their surroundings (vibrations, heat, etc.)
• Resources:
  • Advanced Material Science: Materials that are self-healing, adaptable, and infinitely recyclable.  
  • 3D/4D Printing: On-demand manufacturing using recycled and bio-based materials.
  • Urban Mining: Highly efficient systems for recovering resources from existing infrastructure and waste.
• Environment:
  • Atmospheric Carbon Capture: Large-scale systems to remove CO2 and other pollutants from the air.
  • Ocean Remediation: Technologies to clean up pollution and restore marine ecosystems.
  • Geoengineering: Advanced, carefully managed techniques to regulate climate and mitigate natural disasters.
• Agriculture:
  • Vertical Farming: Multi-story, highly efficient farms in urban areas.
  • Precision Agriculture: AI-powered systems to optimize resource use in farming.  
  • Lab-Grown Food: Meat and other food products produced in labs, reducing land and resource use.
• Information Technology:
  • AI for Sustainability: AI systems to manage resources, optimize energy grids, and monitor ecosystems.  
  • Quantum Computing: Potentially revolutionizing materials science, medicine, and other fields crucial for sustainability.  

Important Considerations:

• Ethical Development: Technologies will need to be developed and used responsibly, with careful consideration of their social and environmental impacts.
• Global Cooperation: Addressing global challenges like climate change will require international collaboration on technology development and deployment.
• Resilience: Sustainable technologies will need to be resilient to extreme weather events and other disruptions caused by climate change.

In essence, sustainable technology in 2520 will likely be about creating a truly circular economy where human needs are met in a way that enhances, rather than degrades, the planet’s ecosystems.Sources and related content

Who is required Sustainable Technology of 2520 ?

It’s more accurate to say that sustainable technology in 2520 will be essential for everyone, rather than just required by specific groups. Here’s why:

• Planetary Survival: By 2520, the consequences of climate change and resource depletion will likely be far more severe. Sustainable technology will be crucial for mitigating these effects and ensuring the planet remains habitable for future generations. This means everyone will depend on it for basic needs like clean air, water, and food production.
• Resource Scarcity: As resources become scarcer, sustainable technologies will be necessary for efficient resource management and closed-loop systems. This will impact every aspect of life, from manufacturing and transportation to agriculture and daily consumption.
• Economic Stability: In a world facing environmental challenges, sustainable technologies will drive economic growth by creating new industries, jobs, and solutions. Nations and communities that embrace sustainability will be more resilient and prosperous.  
• Social Equity: Sustainable technologies can help address inequalities by ensuring access to essential resources and opportunities for all. This includes clean energy, sustainable agriculture, and equitable access to technology.  

However, some groups might have a greater role or responsibility in developing and implementing sustainable technology:

• Scientists and Engineers: They will be at the forefront of developing new sustainable technologies and finding solutions to environmental challenges.
• Governments and Policymakers: They will need to create policies and regulations that incentivize sustainable practices and ensure equitable access to resources.  
• Businesses and Industries: They will need to adopt sustainable practices and invest in sustainable technologies to reduce their environmental impact.  
• Individuals: Everyone will have a role to play in adopting sustainable lifestyles and making conscious choices that support a sustainable future.

Ultimately, sustainable technology in 2520 will be a collective effort, requiring collaboration and responsibility from all members of society to ensure a healthy planet and a thriving future for all.Sources and related content

When is required Sustainable Technology of 2520 ?

This is a tricky question! It’s not about a specific date, but rather a continuous and increasingly urgent need. Here’s how to think about it:

• The need is NOW: We already need sustainable technology to address climate change, resource depletion, and environmental degradation. The sooner we develop and implement these technologies, the better our chances of a positive future.
• The urgency increases over time: As environmental challenges worsen, the need for sustainable technology becomes more critical. By 2520, it will likely be absolutely essential for human survival and well-being.  
• It’s a gradual process: Developing and implementing sustainable technology is not a one-time event. It’s an ongoing process of innovation, adaptation, and improvement. We need to start now and continue to make progress over time.  

Think of it like this:

Imagine a slowly leaking dam. We need to start fixing it now to prevent a catastrophic flood later. The longer we wait, the more urgent the situation becomes, and the more drastic the measures we’ll need to take.

In short:

The “when” for sustainable technology is not a point in the future, but a continuous and pressing need that starts now and will only grow more urgent over time.Sources and related content

COURTESY : RBC

Where is required Sustainable Technology of 2520 ?

You’re right to think about the “where” of sustainable technology in 2520! It won’t be confined to just one place. Here’s a breakdown of where it will likely be integrated:

• Everywhere on Earth:
  • Cities: Sustainable technologies will be essential for urban living, including smart grids, green buildings, efficient transportation, and waste management systems.
  • Rural Areas: Sustainable agriculture, renewable energy generation, and resource management will be crucial for supporting rural communities and preserving ecosystems.
  • Remote Locations: Sustainable technologies will enable human habitation in challenging environments, such as deserts, polar regions, and even underwater.
• Beyond Earth:
  • Space: As humanity expands beyond Earth, sustainable technologies will be needed for space stations, lunar bases, and even interplanetary travel. This includes closed-loop life support systems, resource extraction from celestial bodies, and sustainable energy generation in space.
• In everyday objects:
  • Homes: Homes will likely be equipped with smart systems that optimize energy use, manage resources, and even produce food.  
  • Personal Devices: Our devices will likely be powered by ambient energy harvesting and made from sustainable, recyclable materials.
  • Infrastructure: Roads, bridges, and other infrastructure will be built with sustainable materials and designed to minimize environmental impact.

Essentially, sustainable technology in 2520 will be woven into the fabric of daily life, both on Earth and beyond. It will be an integral part of how we live, work, and interact with the environment.

Think of it like electricity today: it’s not confined to power plants, but rather powers our homes, businesses, and transportation systems. Similarly, sustainable technology in 2520 will be ubiquitous and essential for a thriving future.

How is required Sustainable Technology of 2520 ?

You’re asking about the “how” – the methods and approaches that will be necessary to achieve sustainable technology by 2520. Here’s a breakdown:

1. Continuous Innovation and Research:

• Fundamental Science: Investing in basic research to understand natural systems and discover new materials and processes.
• Applied Engineering: Translating scientific discoveries into practical technologies and solutions.
• Interdisciplinary Collaboration: Fostering collaboration between scientists, engineers, designers, and social scientists to create holistic solutions.  

2. Systems Thinking:

• Life Cycle Assessment: Evaluating the environmental impact of technologies from cradle to grave, considering resource extraction, manufacturing, use, and disposal.
• Closed-Loop Design: Designing systems that minimize waste and maximize resource recovery, mimicking natural ecosystems.  
• Resilience and Adaptability: Creating technologies that can withstand environmental changes and adapt to evolving needs.

3. Technological Advancement:

• Artificial Intelligence: Using AI to optimize energy grids, manage resources, and monitor ecosystems.  
• Biotechnology: Harnessing biological systems for sustainable manufacturing, agriculture, and environmental remediation.
• Nanotechnology: Developing new materials and processes at the nanoscale for enhanced efficiency and sustainability.

4. Policy and Governance:

• Incentives and Regulations: Creating policies that encourage sustainable practices and discourage environmentally harmful activities.  
• International Cooperation: Collaborating across borders to address global challenges like climate change and resource depletion.  
• Ethical Frameworks: Establishing guidelines for the responsible development and use of sustainable technologies.  

5. Education and Awareness:

• Public Engagement: Raising awareness about sustainability issues and empowering individuals to make informed choices.
• Education and Training: Developing educational programs to train the next generation of sustainable technology innovators and practitioners.

6. Economic and Social Factors:

• Sustainable Business Models: Encouraging businesses to adopt sustainable practices and invest in sustainable technologies.
• Social Equity: Ensuring that sustainable technologies benefit all members of society and do not exacerbate existing inequalities.

In essence, achieving sustainable technology by 2520 will require a multi-faceted approach that combines scientific innovation, systems thinking, policy support, and societal engagement. It will be an ongoing process of learning, adapting, and improving our technologies and practices to ensure a sustainable future for all.Sources and related content

Case study is Sustainable Technology of 2520 ?

It’s impossible to provide a real case study of sustainable technology in 2520, as it’s far in the future. However, we can create a hypothetical case study based on current trends and extrapolations, to illustrate what such a technology might look like.

Hypothetical Case Study: The Global Atmospheric Regeneration Network (GARN)

Context: By 2520, climate change has significantly altered the Earth’s ecosystems. Extreme weather events are common, and air quality in many regions is severely compromised. The Global Atmospheric Regeneration Network (GARN) is a crucial technology developed to address these challenges.

Technology: GARN is a global network of interconnected facilities that actively capture and process atmospheric pollutants, including greenhouse gases, particulate matter, and other harmful substances. It utilizes a combination of advanced technologies:

• Bio-Integrated Filters: Large-scale bio-reactors containing genetically engineered microorganisms that efficiently absorb and break down pollutants. These organisms are integrated into vertical “forests” of interconnected tubes, maximizing surface area and efficiency.
• Direct Air Capture: Advanced materials that selectively bind to CO2 and other greenhouse gases, allowing for their capture and subsequent processing.
• Solar-Powered Energy Grid: GARN facilities are powered by a network of space-based solar farms, ensuring a clean energy source for their operation.
• AI-Powered Optimization: A sophisticated AI system constantly monitors atmospheric conditions and adjusts the operation of GARN facilities in real-time to maximize their effectiveness.

Operation: GARN operates as a distributed network, with facilities located strategically around the globe. Air is drawn into the bio-integrated filters and direct air capture units, where pollutants are removed. The cleaned air is then released back into the atmosphere. Captured greenhouse gases are processed and converted into usable products, such as biofuels or raw materials for manufacturing. The AI system continuously analyzes data from weather stations, air quality sensors, and GARN facilities themselves to optimize performance and adapt to changing conditions.

Impact:

• Improved Air Quality: GARN significantly reduces air pollution, leading to improved respiratory health and reduced incidence of related diseases.
• Climate Change Mitigation: By removing greenhouse gases from the atmosphere, GARN helps to mitigate climate change and stabilize global temperatures.
• Ecosystem Restoration: Cleaner air and a more stable climate contribute to the restoration of damaged ecosystems and the preservation of biodiversity.
• Resource Generation: The conversion of captured pollutants into usable products creates valuable resources and supports a circular economy.

Challenges:

• Maintenance: Maintaining a global network of complex facilities requires significant resources and expertise.
• Scalability: Scaling up the technology to meet global needs presents a significant engineering challenge.
• Adaptation: GARN must be able to adapt to changing atmospheric conditions and new pollutants.
• Security: Protecting the network from sabotage or misuse is crucial.

Conclusion: GARN is a hypothetical example of a sustainable technology that could play a vital role in addressing environmental challenges in the future. It highlights the importance of combining advanced scientific knowledge, engineering expertise, and systems thinking to create solutions that are both effective and sustainable. While this is a fictional example, it illustrates the kinds of solutions we might need and the scale at which they might operate in a future dedicated to sustainability.

COURTESY : SUSTAINABLE TECHNOLOGY SOLUTIONS

White paper on Sustainable Technology of 2520 ?

White Paper: Sustainable Technology in 2520: A Vision for a Thriving Future

Abstract:

This white paper explores the potential landscape of sustainable technology in the year 2520, extrapolating from current trends and scientific advancements. It envisions a future where technology plays a crucial role in addressing global challenges such as climate change, resource depletion, and environmental degradation, ensuring a thriving planet for generations to come. The paper examines key technological domains, societal implications, and the necessary steps to realize this vision.

1. Introduction:

The 26th century presents both immense challenges and unprecedented opportunities for humanity. The cumulative effects of climate change, resource scarcity, and population growth necessitate a paradigm shift towards sustainable practices. This paper posits that sustainable technology will be the cornerstone of this transformation, enabling us to live in harmony with the planet and build a prosperous future for all.

2. Key Technological Domains:

2.1. Energy:

• Fusion Energy Dominance: Fusion power, if realized, will provide a clean, abundant, and virtually inexhaustible energy source, powering civilization without the environmental burdens of fossil fuels.
• Space-Based Solar Power: Large-scale solar arrays in orbit will capture sunlight unimpeded by atmospheric interference, beaming clean energy to Earth.
• Ambient Energy Harvesting: Devices will seamlessly harvest energy from their surroundings – vibrations, heat, movement – powering small-scale systems and reducing reliance on centralized grids.

2.2. Resource Management:

• Circular Economy: Closed-loop systems will be the norm, with near-total resource recovery and recycling. “Waste” as we know it will be a relic of the past.
• Advanced Materials Science: Self-healing, adaptable, and infinitely recyclable materials will revolutionize manufacturing and construction, minimizing resource consumption.
• Precision Resource Extraction: AI-powered systems will optimize resource extraction from the Earth and even celestial bodies, minimizing environmental disruption.

2.3. Environmental Remediation:

• Atmospheric Carbon Capture and Conversion: Large-scale systems will actively remove greenhouse gases from the atmosphere, converting them into useful products.
• Ocean and Ecosystem Restoration: Advanced technologies will be deployed to clean up pollution, restore damaged ecosystems, and enhance biodiversity.
• Geoengineering (Cautious Application): Carefully managed geoengineering techniques may be used to mitigate extreme weather events and stabilize the climate, but only as a last resort and with meticulous oversight.

2.4. Sustainable Agriculture and Food Production:

• Vertical Farming and Controlled Environment Agriculture: Highly efficient, localized food production systems in urban areas will minimize land use and resource consumption.
• Precision Agriculture: AI-powered systems will optimize irrigation, fertilization, and pest control, maximizing yields while minimizing environmental impact.
• Cultivated Meat and Alternative Proteins: Lab-grown meat and other protein alternatives will reduce reliance on traditional animal agriculture, freeing up land and reducing greenhouse gas emissions.

2.5. Information Technology for Sustainability:

• AI-Driven Optimization: AI will play a central role in managing energy grids, optimizing resource allocation, and monitoring environmental conditions.
• Quantum Computing: Quantum computing may revolutionize materials science, drug discovery, and other fields critical for developing sustainable solutions.
• Global Environmental Monitoring Network: A comprehensive network of sensors and satellites will provide real-time data on the health of the planet, enabling proactive intervention and adaptive management.

3. Societal Implications:

• Sustainable Lifestyles: Individuals will adopt sustainable practices in their daily lives, driven by both necessity and a greater awareness of their impact on the planet.
• Global Cooperation: International collaboration will be essential for addressing global challenges and ensuring equitable access to sustainable technologies.
• Ethical Considerations: Careful consideration must be given to the ethical implications of new technologies, ensuring they are used responsibly and for the benefit of all.

4. Path to 2520:

• Invest in Research and Development: Sustained investment in fundamental research and applied engineering is crucial for developing the sustainable technologies of the future.
• Promote Education and Awareness: Educating the public about sustainability and empowering individuals to make informed choices is essential for driving societal change.
• Foster Collaboration and Innovation: Creating a global ecosystem of collaboration between scientists, engineers, policymakers, and businesses is critical for accelerating the development and deployment of sustainable technologies.

5. Conclusion:

The vision of a sustainable future in 2520 is within reach. By embracing innovation, fostering collaboration, and prioritizing ethical considerations, we can create a world where technology empowers us to live in harmony with the planet, ensuring a thriving future for generations to come. This requires action now to lay the foundations for the sustainable technologies of tomorrow.

Industrial application of Sustainable Technology of 2520 ?

Let’s imagine some industrial applications of sustainable technology in 2520, building upon the previous discussions:

1. Advanced Manufacturing:

• Closed-Loop Factories: Factories operate on closed-loop principles, where all waste is recycled and reused within the production process. Raw materials are sourced sustainably or created from recycled materials.  
• 4D Printing: Materials can be programmed to change shape over time in response to environmental stimuli, allowing for dynamic adaptation in manufacturing processes and product design. Imagine self-assembling or adapting products.  
• Bio-Integrated Manufacturing: Biological systems are used to produce materials and products, reducing reliance on fossil fuels and creating biodegradable alternatives. Think of factories growing materials rather than just assembling them.  

2. Resource Extraction and Processing:

• Precision Mining: AI-powered robots and drones precisely target and extract resources with minimal environmental impact, reducing habitat destruction and waste. Even asteroid mining becomes sustainable.  
• Urban Mining: Highly efficient facilities recover valuable materials from existing infrastructure and waste streams, creating a circular economy and reducing the need for primary resource extraction.  
• Advanced Material Refining: Nanotechnology and other advanced techniques are used to refine and process resources with near-perfect efficiency, minimizing energy consumption and waste.

3. Energy Production and Distribution:

• Fusion Power Plants: Fusion reactors provide clean and abundant energy to power industrial processes, eliminating reliance on fossil fuels.
• Space-Based Solar Farms: Large-scale solar arrays in orbit beam clean energy to industrial facilities around the globe, providing a continuous and reliable power supply.
• Smart Grids: AI-powered grids optimize energy distribution and consumption in real-time, maximizing efficiency and minimizing waste.  

4. Transportation and Logistics:

• Autonomous Electric Vehicles: Fleets of autonomous electric vehicles powered by clean energy transport goods and materials, reducing emissions and traffic congestion.
• Hyperloops and Maglev Trains: High-speed transportation systems powered by renewable energy connect industrial centers, enabling rapid and sustainable movement of goods and people.
• Sustainable Aviation: Biofuel-powered aircraft or potentially even more advanced propulsion systems minimize the environmental impact of air travel for both passengers and cargo.

5. Construction and Infrastructure:

• Self-Healing Materials: Buildings and infrastructure are constructed from self-healing materials that automatically repair damage, extending their lifespan and reducing maintenance costs.
• Modular Construction: Buildings are assembled from modular components that can be easily reconfigured or recycled, minimizing waste and maximizing flexibility.  
• Green Building Technologies: Buildings generate their own energy, use sustainable materials, and minimize their environmental footprint.  

6. Agriculture and Food Production:

• Vertical Farms: Multi-story vertical farms located in urban areas produce food locally, reducing transportation costs and environmental impact.  
• Precision Agriculture: AI-powered systems optimize resource use in agriculture, maximizing yields while minimizing water consumption, fertilizer use, and pesticide application.  
• Biomanufacturing of Food: Cultivated meat and other protein alternatives are produced in labs, reducing the need for traditional animal agriculture and its associated environmental impacts.  

These are just a few examples of how sustainable technology could revolutionize industry in 2520. The key principles will be radical efficiency, closed-loop systems, and harmony with nature, leading to a more sustainable and prosperous future.Sources and related content

Research and development of Sustainable Technology of 2520 ?

You’re asking about the process of research and development that would be necessary to bring about sustainable technology by 2520. It’s a long-term vision requiring sustained effort across many fronts. Here’s a breakdown:

1. Foundational Science:

• Materials Science: Discovering new materials with unique properties like self-healing, extreme durability, and adaptability. This involves exploring nanotechnology, biomimicry, and even potentially new forms of matter.  
• Energy Physics: Deepening our understanding of fusion, exploring alternative energy sources (like zero-point energy, if it proves feasible), and developing highly efficient energy conversion and storage technologies.
• Environmental Science: Studying complex ecosystems to understand their resilience, identify tipping points, and develop strategies for restoration and protection.
• Biotechnology: Researching genetic engineering, synthetic biology, and other biological tools to develop sustainable agriculture, biomanufacturing, and bioremediation technologies.  

2. Applied Engineering:

• Systems Engineering: Designing complex systems that integrate multiple sustainable technologies, such as smart grids, closed-loop manufacturing processes, and global environmental monitoring networks.
• AI and Machine Learning: Developing advanced AI algorithms for optimizing energy use, managing resources, and predicting environmental changes.  
• Robotics and Automation: Creating robots and automated systems for precision resource extraction, environmental cleanup, and sustainable manufacturing.  
• Infrastructure Development: Designing and building sustainable infrastructure, including green buildings, high-speed transportation networks, and resilient urban systems.

3. Interdisciplinary Collaboration:

• Collaboration between scientists and engineers: Translating scientific discoveries into practical technologies requires close collaboration between researchers from different disciplines.
• Partnerships between academia, industry, and government: Accelerating innovation requires partnerships between universities, companies, and government agencies.
• Engagement with social scientists and ethicists: Ensuring that sustainable technologies are developed and used responsibly requires considering their social and ethical implications.

4. Experimental Platforms and Testbeds:

• Large-scale testbeds: Creating real-world environments to test and refine sustainable technologies, such as smart cities, eco-villages, and closed-loop industrial parks.
• Digital twins: Developing virtual models of complex systems to simulate and optimize the performance of sustainable technologies.  
• International research collaborations: Pooling resources and expertise through global research initiatives to address shared challenges.  

5. Continuous Learning and Adaptation:

• Monitoring and evaluation: Tracking the performance of sustainable technologies and identifying areas for improvement.
• Adaptive management: Adjusting strategies and technologies based on new knowledge and changing conditions.  
• Open innovation: Sharing knowledge and collaborating with others to accelerate the development of sustainable solutions.  

Important Considerations:

• Long-term vision: Research and development of sustainable technology requires a long-term perspective and sustained investment.
• Risk-taking and experimentation: Innovation involves taking risks and experimenting with new ideas, even if they may not always succeed.  
• Ethical considerations: It is crucial to consider the ethical implications of new technologies and ensure they are used responsibly.

The research and development of sustainable technology for 2520 is not just about inventing new gadgets. It’s about fundamentally changing the way we live and interact with the planet. It’s a grand challenge that requires a global effort and a commitment to a sustainable future.Sources and related content

COURTESY : Bernard Marr

References

1. ^ “The Economics and Social Benefits of NOAA Ecosystems Data and Products Table of Contents Data Users”. NOAA. Archived from the original on 2010-03-25. Retrieved 2009-10-13.
2. ^ Buchenrieder, G., und A.R. Göltenboth: Sustainable freshwater resource management in the Tropics: The myth of effective indicators, 25th International Conference of Agricultural Economists (IAAE) on “Reshaping Agriculture’s Contributions to Society” in Durban, South Africa, 2003.
3. ^ Jump up to:^a b Krebs (2001) pp. 560–582.
4. ^ University of Copenhagen (March 2009) “Key Messages from the Congress” Archived 2009-03-16 at the Wayback Machine News item on Copenhagen Climate Congress in March 2009. Retrieved on: 2009-03-18.
5. ^ Adams, D. (March 2009) “Stern attacks politicians over climate ‘devastation'”. The Guardian. Retrieved on: 2009-03-18.
6. ^ Hegerl, G.C. et al. (2007). “Climate Change 2007: The Physical Science Basis.” Chapter 9, “Understanding and Attributing Climate Change.” Contribution of Working Group 1 to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. p. 676. Cambridge: Cambridge University Press. Full report at: [1] IPCC Report. Retrieved on: 2009-03-18.
7. ^ Kerr, R.A. (2004). “A slowing cog in the North Atlantic ocean’s climate machine.” Science 304: 371–372.[2] Retrieved on: 2009-04-19.
8. ^ Black, R. (November 2006). “‘Only 50 years left’ for sea fish”. BBC News, UK.
9. ^ Harrabin, R. (March 2009). “‘Coral lab’ offers acidity insight”. BBC News, UK. Retrieved on: 2009-03-18.
10. ^ Schukman, D. (March 2009). “Sea rise ‘to exceed expectations'”. BBC News, UK. Retrieved on: 2009-03-18.
11. ^ Lindenmayer & Burgman (2005).
12. ^ Jump up to:^a b Clarke & King (2006) pp. 20–21.
13. ^ Jump up to:^a b Hoekstra, A.Y. (2006). “The Global Dimension of Water Governance: Nine Reasons for Global Arrangements in Order to Cope with Local Problems.” Value of Water Research Report Series No. 20 UNESCO-IHE Institute for Water Education. Retrieved on: 2009-03-18.
14. ^ World Wide Fund for Nature (2008). Living Planet Report 2008. Retrieved on: 2009-03-29.
15. ^ Organic Gardening Techniques, Missouri University Extension. October 2004. Retrieved June 17, 2009.
16. ^ Sustainable Gardening & Food Production Archived 2010-06-21 at the Wayback Machine, Daniel Boone Regional Library. Retrieved June 17, 2009
17. ^ World Resources Institute (1998). World Resources 1998–1999. Oxford: Oxford University Press. ISBN 0-19-521408-0.
18. ^ Groombridge & Jenkins (2002).
19. ^ Jump up to:^a b Food and Agriculture Organisation (2006). “Global Forest Resources Assessment 2005: Progress Towards Sustainable Forest Management.” Forestry paper 147. Rome: FAO. Retrieved on: 2009-04-17.
20. ^ IPCC (2006). IPCC Guidelines for National Greenhouse Inventories, Vol.4, Agriculture, Forestry, and other Land Uses. Japan: Institute for Global Environment Strategies.
21. ^ Kinver, M. (April 2009). “Key role of forests ‘may be lost'” BBC News, UK. Retrieved on: 2009-04-19.
22. ^ Dold, M. (April 2009). “New Study Warns Damage to Forests from Climate Change Could Cost the Planet Its Major Keeper of Greenhouse Gases.”. IUFRO News. Retrieved on: 2009-04-20.
23. ^ Food and Agriculture Organization (June 2006). “Food and Agriculture Statistics Global Outlook.” Rome: FAO Statistics Division. Retrieved on: 2009-03-18.
24. ^ Imhoff, M.L. et al. (2004). “Global Patterns in Human Consumption of Net Primary Production.” Nature 429: 870–873.
25. ^ Tudge (2004).
26. ^ World Business Council for Sustainable Development Archived 2009-04-10 at the Wayback Machine This web site has multiple articles on WBCSD contributions to sustainable development. Retrieved on: 2009-04-07.
27. ^ Wilson (2002)
28. ^ Leakey & Lewin (1995)
29. ^ Millennium Ecosystem Assessment, pp. 42–47.
30. ^ Kinver, M. (May 2008). Climate ‘accelerating bird loss. BBC News, UK. Retrieved on: 2009-04-17/
31. ^ BBC News (March 2009) “Climate ‘hitting Europe’s birds’.” BBC News, UK. Retrieved on: 2009-04-17.
32. ^ Gill, V.“The wild ancestors of common domestic fruit trees are in danger of becoming extinct, scientists have warned.” BBC News, UK. Retrieved on: 2009-05-09.
33. ^ Randall (2002).
34. ^ Krebs (2001) pp. 190–205.
35. ^ Blood (2001).
36. ^ John Sterman, “Business Dynamics: Systems Thinking and Modeling for a Complex World, 2000, pp 5-10.