Sustainable Technology of 2750

Sustainable Technology of 2750 ?

While it’s impossible to predict the future with certainty, we can explore some potential sustainable technologies that might exist in 2750 based on current trends and advancements:

Energy:

• Fusion Power: Nuclear fusion, a clean and virtually limitless energy source, could become a reality.
• Advanced Solar: Highly efficient solar panels integrated into infrastructure and even clothing.
• Space-Based Solar: Solar energy collected in space and beamed down to Earth.  
• Energy Storage: Revolutionary battery technology or other storage methods to ensure a stable and reliable energy supply.

Environment:

• Carbon Capture and Sequestration: Advanced technologies to remove CO2 from the atmosphere and store it safely.  
• Ocean Cleanup and Restoration: Large-scale systems to remove plastic and other pollutants from the oceans, and restore marine ecosystems.
• Vertical Farming and Sustainable Agriculture: High-tech farms in urban areas to produce food efficiently with minimal environmental impact.
• Water Purification and Desalination: Advanced methods to provide clean and accessible water to all populations.

Materials:

• Biodegradable and Recyclable Materials: Widespread use of materials that break down naturally or can be easily recycled.
• Self-Healing Materials: Materials that can repair themselves, extending their lifespan and reducing waste.  
• Advanced Construction Techniques: Sustainable building practices using eco-friendly materials and minimizing waste.  

Transportation:

• Electric and Autonomous Vehicles: Widespread use of electric vehicles powered by renewable energy, and self-driving technology to improve safety and efficiency.
• Hyperloop or other High-Speed Transport: Advanced transportation systems to reduce travel times and connect cities more efficiently.
• Sustainable Aviation: Aircraft powered by biofuels or other clean energy sources.  

Other:

• Artificial Intelligence and Machine Learning: Used to optimize resource use, predict environmental changes, and develop new sustainable technologies.  
• Biotechnology: Used to develop new biofuels, create biodegradable materials, and improve agricultural practices.
• Nanotechnology: Used to create more efficient solar cells, develop new materials, and improve water purification methods.  

It’s important to remember that these are just some possibilities, and the actual technologies that exist in 2750 could be very different. However, the focus on sustainability and environmental protection is likely to remain a key driver of technological development in the future.Sources and related content

Who is required Sustainable Technology of 2750 ?

It’s more accurate to say that sustainable technology in 2750 would be essential for everyone. Here’s why:

• Environmental Necessity: By 2750, the consequences of unsustainable practices might be far more severe. Extreme weather, resource scarcity, and pollution could make survival challenging without advanced sustainable solutions.
• Resource Management: A growing population and dwindling resources would necessitate efficient technologies for energy production, food production, and waste management.
• Economic Viability: Sustainable technologies would likely be the foundation of the global economy, driving innovation and creating new industries.
• Quality of Life: Clean energy, clean water, and a healthy environment would be crucial for maintaining a good quality of life for all people.

In essence, sustainable technology in 2750 would be less of a choice and more of a fundamental requirement for human civilization to thrive.

While everyone would benefit from these technologies, some groups might have a particular interest in their development and implementation:

• Scientists and Engineers: They would be at the forefront of developing and refining these technologies.
• Governments and Policymakers: They would play a crucial role in promoting and regulating the use of sustainable technologies.
• Businesses: Companies that embrace sustainability would have a competitive advantage and contribute to a healthier planet.  
• Individuals: Everyone would have a stake in ensuring access to clean energy, clean water, and a sustainable environment.

Ultimately, the need for sustainable technology in 2750 would unite humanity in a common goal: to protect the planet and ensure a prosperous future for all.

When is required Sustainable Technology of 2750 ?

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: Many of the seeds for sustainable technology in 2750 need to be planted today. Research, development, and implementation take time. The sooner we start, the better prepared we’ll be.
• A Gradual Transition: Sustainable technology won’t suddenly appear in 2750. It will be a result of ongoing innovation and adoption over centuries. Each generation will build upon the progress of the last.
• Responding to Challenges: The need for sustainable technology will become even more critical as we face increasing environmental challenges like climate change, resource depletion, and pollution. The urgency will grow as these problems worsen.
• A Moving Target: The specific technologies needed in 2750 will depend on the state of the world at that time. We can’t predict the future, but we can anticipate the need for solutions that address the fundamental challenges of sustainability.

In short, the need for sustainable technology is constant and evolving. It’s not about a deadline, but about a commitment to a long-term vision of a healthy planet and a thriving civilization.

We need to be working towards that vision now, and every generation will need to continue that work.

COURTESY : Voith Group

Where is required Sustainable Technology of 2750 ?

Sustainable technology in 2750, or even the path leading up to it, will be required everywhere. Sustainability isn’t a localized issue; it’s a global imperative. Here’s a breakdown:

• Globally: Many environmental challenges, like climate change, ocean pollution, and biodiversity loss, transcend national borders. International cooperation and shared technologies will be essential.  
• Locally: Sustainable solutions will need to be adapted to specific regional contexts. Different ecosystems, climates, and resource availabilities will require tailored approaches. Local communities will need to be involved in developing and implementing these solutions.  
• In Urban Areas: Cities are centers of consumption and waste generation. Sustainable urban planning, transportation, energy systems, and waste management will be crucial.  
• In Rural Areas: Sustainable agriculture, resource management, and infrastructure development will be essential for supporting rural communities and preserving natural ecosystems.  
• In Developed Nations: These countries have a responsibility to lead the way in developing and deploying sustainable technologies, and to support developing nations in their efforts.
• In Developing Nations: Access to sustainable technologies is crucial for these countries to achieve economic development without exacerbating environmental problems.
• Even in Space: As humanity expands beyond Earth, sustainable practices will be necessary for space exploration and colonization.  

Essentially, sustainable technology in 2750 (and long before) will be required in every corner of the planet, and even beyond. It’s a universal need, and its development and implementation will require a collaborative, global effort.Sources and related conten

Case study is Sustainable Technology of 2750 ?

It’s difficult to create a case study of sustainable technology in 2750 in the traditional sense, as that implies examining a real-world example. We don’t have a real-world example of 2750. However, we can create a hypothetical case study, a thought experiment, to illustrate what sustainable technology might look like then. Here’s an attempt:

Hypothetical Case Study: The Integrated Eco-City of Aurora, 2750

Background: By 2750, climate change has significantly reshaped the planet. Coastal cities are largely submerged, and extreme weather events are commonplace. Aurora is one of a network of eco-cities designed to be fully self-sufficient and resilient.

Sustainable Technologies in Aurora:

• Energy: Aurora is powered by a combination of space-based solar energy beamed to the city and locally generated fusion power. Excess energy is stored in advanced, high-capacity storage systems.
• Food: Vertical farms integrated into the city’s architecture produce a variety of crops using hydroponics and aeroponics. Cultivated meat and other protein alternatives are also produced locally.
• Water: Water is harvested from the atmosphere and recycled through advanced purification systems. Desalination plants powered by renewable energy provide additional water as needed.
• Waste: A closed-loop waste management system processes all waste into reusable materials or energy. Nothing is truly wasted.  
• Transportation: Personal transportation is primarily via electric, autonomous vehicles powered by the city’s energy grid. High-speed, maglev trains connect Aurora to other eco-cities.
• Materials: Buildings are constructed from self-healing, biodegradable materials. Advanced recycling systems ensure that resources are constantly reused.  
• Environment: Aurora is designed to integrate seamlessly with the surrounding ecosystem. Green spaces and wildlife corridors are incorporated into the city’s design. AI-powered systems monitor the environment and optimize resource use.  

Challenges and Solutions:

• Maintaining System Stability: Ensuring the continuous operation of complex systems like energy grids and waste management requires sophisticated AI and constant monitoring.
• Adapting to Change: Climate change continues to impact the planet. Aurora is designed to be adaptable, with systems that can be adjusted to changing conditions.
• Social Equity: Ensuring that all residents have equal access to resources and opportunities is a key priority.

Lessons Learned (Hypothetical):

• Interconnectedness: All of Aurora’s systems are interconnected, demonstrating the importance of a holistic approach to sustainability.
• Resilience: The city’s design emphasizes resilience, allowing it to withstand environmental challenges and other disruptions.
• Technological Advancement: The advanced technologies used in Aurora highlight the importance of continuous innovation in achieving sustainability.

Conclusion:

Aurora represents a potential future where sustainable technology is not just a set of tools, but a way of life. It demonstrates how human ingenuity, combined with a commitment to environmental stewardship, can create thriving, resilient communities in a changing world.

Important Note: This is a fictional case study. Its purpose is to illustrate the kinds of technologies and systems that might exist in a sustainable future. It’s not a prediction of what will exist. The real future of sustainable technology will depend on the choices we make today.Sources and related content

COURTESY : Tech Evaluate

White paper on Sustainable Technology of 2750 ?

White Paper: Sustainable Technology in 2750: A Vision for a Thriving Future

Abstract:

This white paper explores the potential landscape of sustainable technology in the year 2750. It extrapolates from current trends and emerging technologies to envision a future where humanity has achieved a harmonious balance with the planet, ensuring a thriving civilization for generations to come. The paper examines key areas including energy, environment, materials, transportation, and societal integration, highlighting the interconnectedness of these domains and the crucial role of continuous innovation and global cooperation.

1. Introduction:

The challenges of the 21st century, including climate change, resource depletion, and pollution, necessitate a fundamental shift towards sustainable practices. This paper looks centuries into the future, not to predict the precise technologies that will exist, but to explore the kinds of technologies and societal structures that might be necessary to achieve long-term sustainability. It presents a vision of 2750 where advanced technologies, coupled with a deep understanding of ecological principles, enable humanity to flourish within the Earth’s carrying capacity.

2. Energy:

By 2750, the reliance on fossil fuels will be a distant memory. The energy landscape will likely be dominated by:

• Fusion Power: Safe, clean, and abundant fusion energy will provide the primary source of power for cities and industries.
• Space-Based Solar: Massive solar arrays in orbit will capture sunlight unimpeded by the atmosphere, beaming clean energy to Earth.
• Advanced Solar: Highly efficient solar cells integrated into buildings, infrastructure, and even personal devices will supplement energy needs.
• Advanced Energy Storage: Revolutionary energy storage solutions will ensure a stable and reliable energy supply, overcoming the intermittency challenges of renewable sources.

3. Environment:

Restoring and protecting Earth’s ecosystems will be paramount. Key technologies will include:

• Carbon Capture and Sequestration: Advanced systems will actively remove CO2 from the atmosphere, mitigating the effects of past emissions.
• Ocean Cleanup and Restoration: Autonomous systems will patrol the oceans, removing pollutants and restoring damaged ecosystems.
• Precision Agriculture: Advanced techniques will optimize food production while minimizing environmental impact, reducing the need for vast agricultural lands.
• Ecosystem Monitoring and Management: AI-powered systems will monitor the health of ecosystems and provide real-time data to inform conservation efforts.

4. Materials:

The concept of “waste” will be largely obsolete. Key advancements will include:

• Biodegradable and Recyclable Materials: Most materials will be designed to break down naturally or be easily recycled, creating a circular economy.
• Self-Healing Materials: Materials that can repair themselves will extend the lifespan of products and infrastructure, reducing the need for replacements.
• Advanced Material Synthesis: New materials with tailored properties will be created using sustainable processes.

5. Transportation:

Sustainable transportation systems will be essential for connecting communities and facilitating trade. Key technologies may include:

• Electric and Autonomous Vehicles: Personal transportation will be dominated by electric vehicles powered by clean energy, with self-driving technology enhancing safety and efficiency.
• High-Speed Rail and Maglev Systems: Advanced rail networks will provide fast and efficient transportation between cities and regions.
• Sustainable Aviation: Aircraft powered by biofuels or other clean energy sources will minimize the environmental impact of air travel.

6. Societal Integration:

Sustainable technology will be deeply integrated into society, shaping how we live and interact with the world. Key aspects will include:

• Smart Cities: Urban centers will be designed to optimize resource use and minimize environmental impact.
• Decentralized Systems: Communities will have greater control over their energy and resources, fostering resilience and self-sufficiency.
• Global Cooperation: International collaboration will be essential for addressing global challenges and ensuring equitable access to sustainable technologies.

7. Challenges and Opportunities:

Achieving this vision of sustainable technology in 2750 will present significant challenges:

• Technological Development: Continued investment in research and development will be crucial for creating the necessary technologies.
• Economic Transition: Shifting to a sustainable economy will require significant investments and adjustments.
• Social and Ethical Considerations: Ensuring equitable access to sustainable technologies and addressing potential ethical implications will be essential.

However, the opportunities are immense:

• Environmental Restoration: Reversing the damage caused by past unsustainable practices and creating a healthy planet for future generations.
• Economic Prosperity: Creating new industries and jobs in the sustainable technology sector.
• Improved Quality of Life: Providing clean energy, clean water, and a healthy environment for all.

8. Conclusion:

The vision of sustainable technology in 2750 presented in this white paper is ambitious but achievable. By embracing innovation, fostering global cooperation, and prioritizing environmental stewardship, humanity can create a future where technology and nature coexist in harmony, ensuring a thriving civilization for centuries to come. The journey towards this future begins today, with the choices we make and the actions we take to build a more sustainable world.

Industrial application of Sustainable Technology of 2750 ?

It’s fascinating to imagine the industrial applications of sustainable technology in 2750! Here are some possibilities, extrapolating from current trends and imagining how they might evolve over centuries:

1. Advanced Manufacturing and Production:

• Closed-loop Production Systems: Factories of the future could operate on closed-loop systems, where all waste is recycled and reused within the production process. This would minimize resource depletion and pollution.  
• Personalized Manufacturing: 3D printing and other advanced manufacturing techniques could enable highly personalized production, with goods tailored to individual needs and preferences. This could reduce waste and increase efficiency.  
• AI-Powered Optimization: Artificial intelligence could be used to optimize every aspect of the manufacturing process, from design and material selection to production and distribution. This would lead to greater efficiency and reduced environmental impact.  

2. Energy-Intensive Industries:

• Sustainable Steel Production: Steel production, a traditionally energy-intensive industry, could be revolutionized by technologies like hydrogen-based steelmaking or carbon capture and utilization.  
• Advanced Materials Processing: Industries that rely on rare or energy-intensive materials could develop new processes that use more abundant and sustainable resources.
• Renewable Energy Integration: Industries could be fully integrated with renewable energy sources, such as on-site fusion reactors or direct connections to space-based solar power grids.

3. Resource Extraction and Management:

• Sustainable Mining: Mining operations could utilize advanced technologies to minimize environmental impact, such as autonomous vehicles, precision drilling, and in-situ resource extraction.  
• Resource Recovery: Advanced recycling and resource recovery technologies could enable the extraction of valuable materials from waste streams, reducing the need for virgin resources.  
• Ocean Mining (Sustainable): If ocean mining is necessary, it would likely be done with extreme care, using technologies that minimize disruption to marine ecosystems.

4. Infrastructure Development:

• Self-Healing Infrastructure: Infrastructure, such as roads and bridges, could be built from self-healing materials that can repair themselves, reducing maintenance needs and extending lifespan.  
• Smart Infrastructure: Sensors and AI could be used to monitor the condition of infrastructure and optimize its performance, improving efficiency and safety.  
• Modular Construction: Buildings and other structures could be built using modular designs and sustainable materials, allowing for easy adaptation and reuse.  

5. Biotechnology and Biomanufacturing:

• Bio-based Materials: Industries could utilize bio-based materials derived from plants or other renewable resources, reducing reliance on fossil fuels.  
• Synthetic Biology: Synthetic biology could be used to create new materials, fuels, and other products with minimal environmental impact.  
• Bioremediation: Biological processes could be used to clean up pollution and restore damaged ecosystems.

Important Considerations:

• Automation and Labor: As industries become more automated, it will be crucial to address the potential impact on employment and ensure a just transition for workers.
• Ethical Considerations: The use of advanced technologies like AI and biotechnology will raise ethical questions that need to be carefully considered.
• Global Equity: Ensuring that the benefits of sustainable technology are shared equitably across the globe will be essential for achieving a truly sustainable future.

These are just a few examples of the potential industrial applications of sustainable technology in 2750. The actual technologies that emerge will depend on the challenges we face and the choices we make in the coming centuries. However, the focus on sustainability and environmental protection is likely to remain a key driver of industrial innovation and development.Sources and related content

Research and development of Sustainable Technology of 2750 ?

It’s exciting to think about the kind of research and development that might lead to sustainable technology in 2750! Here are some key areas of focus, keeping in mind that this is speculative and based on extrapolations from current trends:

1. Fundamental Science:

• New Physics: Exploring the fundamental laws of the universe to discover new sources of energy, new forms of matter, and new ways to manipulate both. This could lead to breakthroughs like zero-point energy or manipulating spacetime for energy or transportation.
• Advanced Mathematics: Developing new mathematical frameworks to model complex systems, optimize resource use, and predict environmental changes with greater accuracy.
• Consciousness and AI: Investigating the nature of consciousness to create truly intelligent AI systems that can help solve complex problems related to sustainability.

2. Energy:

• Fusion Energy: Continued research into fusion reactor design, plasma physics, and materials science to make fusion power a practical and efficient energy source.
• Exotic Energy Sources: Exploring more unconventional energy sources like zero-point energy, antimatter, or tapping into the energy of other dimensions (if such things exist!).
• Energy Transmission and Storage: Developing highly efficient and lossless methods for transmitting energy over long distances, and creating revolutionary energy storage solutions that can hold vast amounts of power.

3. Environment:

• Geoengineering: Researching safe and effective methods for manipulating Earth’s climate to reverse the effects of climate change, such as carbon capture and sequestration on a massive scale, solar radiation management, or even weather control.
• Ecosystem Restoration: Developing advanced techniques for restoring damaged ecosystems, such as using nanotechnology to remove pollutants or genetic engineering to revive extinct species.
• Planetary Defense: Researching ways to protect Earth from asteroids, comets, or other cosmic threats that could disrupt the environment.

4. Materials:

• Programmable Matter: Developing materials that can change their properties on demand, allowing for dynamic adaptation to different needs.
• Self-Replicating Materials: Creating materials that can replicate themselves, potentially allowing for the construction of infrastructure or the production of goods with minimal human intervention.
• Exotic Materials: Exploring the potential of new materials with extraordinary properties, such as superconductors that operate at room temperature or materials that can defy gravity.

5. Biotechnology:

• Synthetic Biology: Engineering new biological systems to produce biofuels, create biodegradable materials, or even clean up pollution.
• Genetic Engineering: Using genetic engineering to improve crops, create disease-resistant organisms, or even enhance human capabilities in a sustainable way.
• Xenobiology: Exploring the possibility of creating new forms of life with different genetic codes, potentially leading to new technologies or solutions for environmental problems.

6. Space Exploration and Colonization:

• Advanced Propulsion Systems: Developing new propulsion systems that can enable faster and more efficient space travel, such as warp drives or other theoretical technologies.
• Space Habitats: Designing and building self-sustaining habitats for long-term space missions or even colonization of other planets.
• Terraforming: Researching the possibility of terraforming other planets to make them habitable for humans.

Important Considerations:

• Interdisciplinary Collaboration: Research and development in these areas will require collaboration between scientists from many different fields, as well as engineers, ethicists, and social scientists.
• Ethical Implications: The development of advanced technologies will raise complex ethical questions that need to be carefully considered.
• Long-Term Vision: Research and development for sustainable technology in 2750 will require a long-term vision and a commitment to investing in fundamental science, even if the payoff is not immediately apparent.

The research and development that leads to sustainable technology in 2750 will be a long and challenging journey, but it is a journey that we must begin today if we want to ensure a thriving future for humanity.

courtesy : SUSTAINABLE TECHNOLOGY SOLUTIONS

References

1. ^ “Key Sustainability Issues in the Electronics Industry: Sustainability Industry Report – SCM | Supply Chain Resource Cooperative (SCRC) | North Carolina State University”. scm.ncsu.edu. 2012-06-18. Retrieved 2015-12-16.
2. ^ Jump up to:^a b c d Dziamski, Mario (June 2014). “Sustainable Electronics Report 2014” (PDF). Berlin/ Amstgerdam: Rank a Brand e.V. Retrieved 22 December 2015.
3. ^ Dziamski, Mario (June 2014). “Sustainable Electronics” (PDF). rankabrand.org.
4. ^ Rampell, Catherine (29 October 2013). “Cracking the Apple Trap”. The New York Times.
5. ^ Sahle-Demessie, E. (15 October 2012). “Sustainable Electronics Roadmap” (PDF). US EPA. Retrieved 22 December 2015.
6. ^ “Campaign Platform”. electronicstakeback.com.
7. ^ “E-Waste”. svtc.org.
8. ^ Tansel, Berrin (2017-01-20). “From electronic consumer products to e-wastes: Global outlook, waste quantities, recycling challenges”. Environment International. 98: 35–45. doi:10.1016/j.envint.2016.10.002. ISSN 0160-4120. PMID 27726897.
9. ^ Needhidasan, Santhanam; Samuel, Melvin; Chidambaram, Ramalingam (2014-01-20). “Electronic waste – an emerging threat to the environment of urban India”. Journal of Environmental Health Science and Engineering. 12 (1): 36. doi:10.1186/2052-336X-12-36. ISSN 2052-336X. PMC 3908467. PMID 24444377.
10. ^ Needhidasan, Santhanam; Samuel, Melvin; Chidambaram, Ramalingam (2014-01-20). “Electronic waste – an emerging threat to the environment of urban India”. Journal of Environmental Health Science and Engineering. 12 (1): 36. doi:10.1186/2052-336X-12-36. ISSN 2052-336X. PMC 3908467. PMID 24444377.
11. ^ “About Green Engineering”. EPA.gov. 17 August 2016.
12. Khopkar, S.M. (2004). Environmental Pollution Monitoring And Control. New Delhi: New Age International. p. 299. ISBN 978-81-224-1507-0.
13. ^ Jump up to:^a b Takman, Maria; Svahn, Ola; Paul, Catherine; Cimbritz, Michael; Blomqvist, Stefan; Struckmann Poulsen, Jan; Lund Nielsen, Jeppe; Davidsson, Åsa (2023-10-15). “Assessing the potential of a membrane bioreactor and granular activated carbon process for wastewater reuse – A full-scale WWTP operated over one year in Scania, Sweden”. Science of the Total Environment. 895: 165185. Bibcode:2023ScTEn.89565185T. doi:10.1016/j.scitotenv.2023.165185. ISSN 0048-9697. PMID 37385512. S2CID 259296091.
14. ^ Jump up to:^a b Von Sperling, M. (2007). “Wastewater Characteristics, Treatment and Disposal”. Water Intelligence Online. 6. doi:10.2166/9781780402086. ISSN 1476-1777.  Text was copied from this source, which is available under a Creative Commons Attribution 4.0 International License
15. ^ Jump up to:^a b Jones, Edward R.; van Vliet, Michelle T. H.; Qadir, Manzoor; Bierkens, Marc F. P. (2021). “Country-level and gridded estimates of wastewater production, collection, treatment and reuse”. Earth System Science Data. 13 (2): 237–254. Bibcode:2021ESSD…13..237J. doi:10.5194/essd-13-237-2021. ISSN 1866-3508.
16. ^ “Sanitation”. Health topics. World Health Organization. Retrieved 2020-02-23.
17. ^ George Tchobanoglous; H. David Stensel; Ryujiro Tsuchihashi; Franklin L. Burton; Mohammad Abu-Orf; Gregory Bowden, eds. (2014). Metcalf & Eddy Wastewater Engineering: Treatment and Resource Recovery (5th ed.). New York: McGraw-Hill Education. ISBN 978-0-07-340118-8. OCLC 858915999.
18. ^ Jump up to:^a b “What Are the 3 Main Types of Site Remediation?”. www.ancoenv.net. 2022-09-20. Retrieved 2024-04-25.
19. ^ “The main three types of environmental remediation and reclamation – Anderson Engineering”. 2021-02-25. Retrieved 2024-04-25.
20. ^ LLC, Rationalstat (2023-11-27). “Industrial Wastewater Treatment Market to Reach US$ 19.6 Billion by 2030, Driven by Stringent Environmental Regulations and Growing Demand for Sustainable Water Management Solutions | According to RationalStat”. GlobeNewswire News Room (Press release). Retrieved 2024-04-25.
21. ^ “Sediment Remediation • EnvGuide”. EnvGuide. 2018-02-27. Retrieved 2024-04-25.
22. ^ Retrieved June 16th, 2009. “Urban Waste Management”. Retrieved June 16th, 2009. http://documents1.worldbank.org/curated/en/237191468330923040/pdf/918610v20WP0FM0BE0CATALOGED0BY0WED0.pdf
23. ^ “Advancements in E-Waste Recycling Techniques”. Sustainable Review. Retrieved 2023-04-22.
24. ^ “10 Breakthrough Technologies 2024”. MIT Technology Review. Retrieved 2023-04-22.
25. ^ “What is Bioremediation”. www.hawaii.edu. Retrieved 2024-04-27.
26. ^ “What Is Bioremediation, and How Does It Work (With Examples)?”. Investopedia. Retrieved 2024-04-27.
27. ^ Eric Bonds and Liam Downey, “”Green” Technology and Ecologically Unequal Exchange: The Environmental and Social Consequences of Ecological Modernization in the World-System” in: Journal of World-Systems Research, Volume 18, Issue 2 (http://jwsr.pitt.edu/ojs/index.php/jwsr/article/view/482)
28. ^ Gifford, Georgia (2016-05-14). “Five energy innovations revolutionizing the developing world”. Renewable Energy Focus. 17 (3): 97–98. Bibcode:2016REneF..17…97G. doi:10.1016/j.ref.2016.05.001. ISSN 1755-0084.
29. ^ Asim, Taimoor; Islam, Sheikh; Hemmati, Arman; Khalid, Muhammad (2022-01-14). “A Review of Recent Advancements in Offshore Wind Turbine Technology”. Energies. 15 (2): 579. doi:10.3390/en15020579. ISSN 1996-1073.
30. ^ Taesler, R. (1990/91) Climate and Building Energy Management. Energy and Buildings, Vol. 15–16, pp 599 – 608.
31. ^ United States Patent 6098893 Comfort control system incorporating weather forecast data and a method for operating such a system (Inventor Stefan Berglund)
32. ^ “Global Solar Atlas”. globalsolaratlas.info. Retrieved 2022-08-12.
33. ^ “Energy Sources: Solar”. Department of Energy. Archived from the original on 14 April 2011. Retrieved 19 April 2011.
34. ^ Jump up to:^a b Gabbatiss, Josh (2024-01-12). “Analysis: World will add enough renewables in five years to power US and Canada”. Carbon Brief. Retrieved 2024-02-11.
35. ^ “Global Electricity Review 2024”. Ember. 2024-05-07. Retrieved 2024-09-02.
36. ^ Jump up to:^a b “Sun Machines”. The Economist. ISSN 0013-0613. Retrieved 2024-06-26.
37. ^ “2023 Levelized Cost Of Energy+”. Lazard. Retrieved 2023-06-14.
38. ^ “Executive summary – Renewable Energy Market Update – Analysis”. IEA. June 2023. Retrieved 2023-06-14.
39. ^ “Global Electricity Review 2024”. Ember. 2024-05-07. Retrieved 2024-09-02.
40. ^ Norman, Will (2023-06-13). “Through the roof: 49.5% of world’s PV additions were rooftop in 2022 – SolarPower Europe”. PV Tech. Retrieved 2023-06-14.
41. ^ “Solar PV – Analysis”. IEA. Retrieved 2022-11-10.
42. ^ “www.computational-sustainability.org”. www.computational-sustainability.org. Retrieved 2016-03-25.
43. ^ Gomes, Carla; Dietterich, Thomas; Barrett, Christopher; Conrad, Jon; Dilkina, Bistra; Ermon, Stefano; Fang, Fei; Farnsworth, Andrew; Fern, Alan; Fern, Xiaoli; Fink, Daniel; Fisher, Douglas; Flecker, Alexander; Freund, Daniel; Fuller, Angela (2019-08-21). “Computational sustainability: computing for a better world and a sustainable future”. Communications of the ACM. 62 (9): 56–65. Bibcode:2019CoACM..62…56G. doi:10.1145/3339399. ISSN 0001-0782.
44. ^ Frenkel, Karen A. (1 September 2009). “Computer Science meets environmental science”. Communications of the ACM. 52 (9): 23. doi:10.1145/1562164.1562174.
45. ^ Hahn, Nathan R.; Bombaci, Sara P.; Wittemyer, George (2022-03-21). “Identifying conservation technology needs, barriers, and opportunities”. Scientific Reports. 12 (1): 4802. Bibcode:2022NatSR..12.4802H. doi:10.1038/s41598-022-08330-w. ISSN 2045-2322. PMC 8938523. PMID 35314713.
46. ^ Silvestro, Daniele; Goria, Stefano; Sterner, Thomas; Antonelli, Alexandre (2022-03-24). “Improving biodiversity protection through artificial intelligence”. Nature Sustainability. 5 (5): 415–424. Bibcode:2022NatSu…5..415S. doi:10.1038/s41893-022-00851-6. ISSN 2398-9629. PMC 7612764. PMID 35614933.
47. ^ “CompSustNet: Home”. www.compsust.net. Retrieved 2016-03-25.
48. ^ Guerrero-ibanez, J. A.; Zeadally, S.; Contreras-Castillo, J. (2015-12-01). “Integration challenges of intelligent transportation systems with connected vehicle, cloud computing, and internet of things technologies”. IEEE Wireless Communications. 22 (6): 122–128. doi:10.1109/MWC.2015.7368833. ISSN 1536-1284. S2CID 23948355.
49. ^ Barth, Matthew J.; Wu, Guoyuan; Boriboonsomsin, Kanok (2015-09-01). “Intelligent Transportation Systems and Greenhouse Gas Reductions”. Current Sustainable/Renewable Energy Reports. 2 (3): 90–97. Bibcode:2015CSRER…2…90B. doi:10.1007/s40518-015-0032-y. ISSN 2196-3010.
50. ^ “The Role of Technology in Sustainable Agriculture | Radcliffe’s IPM World Textbook”. ipmworld.umn.edu. Retrieved 2024-04-26.
51. ^ “Sustainable Agriculture Programs | NIFA”. www.nifa.usda.gov. Retrieved 2024-04-27.