Sustainable Technology of 2690

Sustainable Technology of 2690 ?

Unfortunately, I cannot provide specific details about sustainable technology in the year 2690. Predicting the future with such precision is simply not possible.

However, I can offer some insights based on current trends and expert predictions:

• Advanced renewable energy: Solar, wind, and other renewable energy sources will likely be highly advanced and efficient, potentially even surpassing fossil fuels as the primary energy source.
• Circular economy: Technologies that promote reuse, recycling, and waste reduction will be crucial. This could include advanced material science, biodegradable plastics, and closed-loop manufacturing systems.
• Precision agriculture: Technologies that optimize resource use in agriculture, such as vertical farming, AI-powered irrigation, and advanced crop monitoring systems, will be essential for feeding a growing population sustainably.
• Carbon capture and storage: Technologies that capture and store carbon dioxide emissions from industrial processes and even directly from the atmosphere will play a significant role in mitigating climate change.  
• Sustainable transportation: Electric vehicles, advanced battery technology, and alternative transportation systems like high-speed trains and maglev trains will likely dominate the transportation sector.
• Smart cities: Urban centers will be designed with sustainability in mind, incorporating green buildings, efficient public transportation, and smart energy grids.

It’s important to remember that these are just a few possibilities. The future of sustainable technology is constantly evolving, and new innovations and breakthroughs could emerge at any time.

I recommend staying informed about the latest developments in sustainable technology by following reputable sources like scientific journals, industry publications, and government reports.

What is Sustainable Technology of 2690 ?

While predicting the exact nature of sustainable technology in 2690 is impossible, we can speculate based on current trends and expert predictions. Here are some possibilities:

1. Advanced Renewable Energy:

• Highly efficient solar: Imagine solar panels not just on rooftops but integrated into roads, buildings, and even clothing, seamlessly harvesting energy from the sun.
• Space-based solar: Solar energy could be collected in space and beamed down to Earth, providing a constant and abundant source of clean energy.  
• Fusion power: If nuclear fusion becomes viable, it could provide a near-limitless source of clean energy, revolutionizing how we power our world.  
• Advanced energy storage: Technologies like advanced batteries, pumped hydro storage, or even entirely new methods could store vast amounts of renewable energy, ensuring a stable and reliable power supply.

2. Circular Economy:

• Material science breakthroughs: Materials that can be easily recycled or even biodegrade on demand could become commonplace, minimizing waste and pollution.
• Closed-loop manufacturing: Products could be designed to be disassembled and reused at the end of their life, creating a circular flow of resources.  
• AI-powered waste management: Smart systems could optimize waste sorting and recycling, ensuring that valuable materials are recovered and reused.  

3. Precision Agriculture:

• Vertical farming: Multi-story farms in urban areas could grow crops with minimal land and water use, reducing transportation costs and environmental impact.  
• AI-powered agriculture: Sensors and AI could monitor crop health, soil conditions, and weather patterns, optimizing irrigation, fertilization, and pest control.  
• Genetic engineering: Crops could be engineered to be more resilient to climate change, require less water and fertilizer, and have higher nutritional value.

4. Carbon Capture and Storage:

• Direct air capture: Technologies could capture carbon dioxide directly from the atmosphere, helping to reverse climate change.
• Carbon mineralization: Captured carbon dioxide could be converted into stable minerals and stored underground, preventing it from re-entering the atmosphere.  
• Industrial carbon capture: Factories and power plants could capture their carbon emissions and store them safely, reducing their environmental impact.  

5. Sustainable Transportation:

• Electric vehicles: Electric vehicles could become the dominant mode of transportation, powered by clean energy sources.
• Advanced battery technology: Batteries with higher energy density, faster charging times, and longer lifespans could make electric vehicles even more appealing.
• Alternative transportation: High-speed trains, maglev trains, and even flying cars could become common, reducing reliance on cars and airplanes.

6. Smart Cities:

• Green buildings: Buildings could be designed to generate their own energy, collect rainwater, and have green spaces, reducing their environmental footprint.
• Smart energy grids: Smart grids could optimize energy distribution and use, reducing waste and improving efficiency.  
• Sustainable infrastructure: Cities could be designed with efficient public transportation, bike lanes, and pedestrian-friendly areas, promoting sustainable living.

7. Other Possibilities:

• Biotechnology: Advances in biotechnology could lead to new ways of producing food, materials, and energy sustainably.
• Nanotechnology: Nanomaterials could be used to create more durable and efficient products, reducing resource use and waste.  
• Artificial intelligence: AI could play a crucial role in optimizing resource use, predicting environmental changes, and developing new sustainable technologies.  

It’s important to remember that these are just a few possibilities. The future of sustainable technology is constantly evolving, and new innovations and breakthroughs could emerge at any time. By staying informed about the latest developments and supporting research and development in sustainable technology, we can help create a more sustainable future for all.

Who is required Sustainable Technology of 2690 ?

It’s more accurate to ask who will benefit from sustainable technology in 2690, rather than who will require it. By that point, sustainable practices will hopefully be so ingrained that they’re simply how things are done.

Here’s a breakdown of who will benefit:

• Humanity as a whole: This is the most important point. Sustainable technology is about ensuring a habitable planet and a good quality of life for future generations. Everyone will benefit from a healthy environment, abundant resources, and a stable climate.
• Ecosystems and biodiversity: Sustainable technology will help protect and restore natural ecosystems, preserving the incredible diversity of life on Earth. This is crucial not just for its own sake, but also because healthy ecosystems provide essential services like clean air and water.  
• Future generations: The choices we make today will have a profound impact on the lives of those who come after us. Sustainable technology is about leaving a legacy of a healthy planet and a thriving society for future generations.
• Developing nations: Sustainable technology can help developing nations leapfrog traditional, polluting technologies and build sustainable economies from the ground up. This can lead to greater equity and a more just world.  
• Businesses: In the long run, sustainability is good for business. Companies that adopt sustainable practices will be more resilient, innovative, and competitive. They will also be better positioned to attract and retain customers who care about the environment and social responsibility.  

It’s important to remember that sustainable technology is not just about environmental protection. It’s also about social and economic development. It’s about creating a world where everyone has access to the resources they need to thrive, both now and in the future.  

In 2690, sustainable technology will hopefully be so advanced and so integrated into our lives that we won’t even think of it as something separate. It will simply be the way we do things.

When is required  Sustainable Technology of 2690  ?

You’re asking a very important question! It’s not about when sustainable technology will be required in 2690, but rather when we need to develop and implement it to ensure a positive future by that time.

Here’s why the timing is crucial:

• Urgency of current environmental challenges: We are already facing the consequences of climate change, pollution, and resource depletion. These problems are not going to solve themselves, and they will only worsen if we don’t take action now.  
• Long-term planning: Developing and implementing sustainable technologies takes time. We need to invest in research and development, build infrastructure, and change our habits. This is not something that can be done overnight.
• Preventing irreversible damage: Some environmental damage may be irreversible. If we wait too long to act, we may reach a point where it is too late to prevent catastrophic consequences.  

Therefore, the answer is NOW. We need to be developing and implementing sustainable technology as rapidly as possible. This is not just about 2690; it’s about ensuring a livable planet for ourselves and for all future generations.

Here are some key points to consider:

• Every action counts: Even small changes in our individual lives can make a difference. By reducing our consumption, using renewable energy, and supporting sustainable businesses, we can all contribute to a more sustainable future.  
• Collaboration is essential: Governments, businesses, and individuals all need to work together to develop and implement sustainable solutions. This requires open communication, shared goals, and a willingness to compromise.  
• Innovation is key: We need to continue to invest in research and development to create new and better sustainable technologies. This includes everything from renewable energy to sustainable agriculture to carbon capture.

The future of sustainable technology depends on the choices we make today. By acting now, we can create a world where future generations can thrive.Sources and related content

Courtesy : Tech Evaluate

Where is required  Sustainable Technology of 2690  ?

That’s a great question! It’s not about a specific location where sustainable technology will be required in 2690. Instead, it’s about everywhere and in everything.

Here’s why:

• Global interconnectedness: The Earth’s systems are interconnected. Pollution in one place can affect the entire planet. Climate change impacts everyone, regardless of where they live. Therefore, sustainable technology needs to be implemented globally.  
• Sustainability in all sectors: Sustainable technology is not just about energy or transportation. It needs to be integrated into all sectors of our economy and society, including agriculture, manufacturing, construction, healthcare, and even entertainment.  
• Urban and rural areas: Sustainable technology is needed in both urban and rural areas. Cities need to become more sustainable through green buildings, efficient public transportation, and smart energy grids. Rural areas need sustainable agriculture, renewable energy, and access to clean water.  
• Personal and public life: Sustainable technology needs to be integrated into both our personal and public lives. We need to adopt sustainable practices in our homes, workplaces, and communities.  

In essence, sustainable technology in 2690 will be required everywhere that human activity takes place. It will be an integral part of how we live, work, and interact with the world around us.

Think of it this way: sustainable technology won’t be confined to specific locations. It will be woven into the fabric of our lives, shaping everything from the energy we use to the food we eat to the products we consume.

To ensure a sustainable future by 2690, we need to be developing and implementing sustainable technologies in all areas of our lives, all across the globe, and starting right now.Sources and related content

How is required  Sustainable Technology of 2690  ?

The question of “how” sustainable technology is required in 2690 is less about the method of requiring it (as if someone would enforce it) and more about how it will function and how it will have become integrated into society by that point. It’s about the nature of its necessity.

Here’s how we can think about it:

• Integrated into everyday life: By 2690, sustainable technology will likely be so deeply integrated into daily life that it won’t be perceived as something separate. It will be the default, the way things are done. Think about how we use electricity today – we don’t think about the complex infrastructure behind it every time we flip a switch. Sustainability will be similar.
• Driven by necessity: By 2690, the consequences of unsustainable practices will likely be so severe that sustainable technology won’t be a choice, but a necessity for survival. Resource scarcity, climate change impacts, and pollution will likely make unsustainable alternatives impossible.
• Self-sustaining systems: Ideally, by 2690, many sustainable systems will be largely self-sustaining. For example, energy grids could be decentralized and powered by renewable sources, requiring minimal maintenance. Circular economies could minimize waste and maximize resource reuse.  
• Embedded in infrastructure: Sustainable technology will be built into the very fabric of our infrastructure. Buildings will be designed to generate their own energy, transportation systems will be electric and efficient, and cities will be planned for sustainability.
• Cultural shift: Perhaps most importantly, by 2690, there will likely be a significant cultural shift towards sustainability. People will understand the importance of living in harmony with the planet and will have adopted sustainable practices as a matter of course.

So, it’s not about “requiring” it in the sense of enforcement. It’s about it becoming the only viable option and being so thoroughly integrated that it’s simply how society functions. It will be a natural consequence of centuries of development and adaptation to the challenges we face today.

Case study is  Sustainable Technology of 2690  ?

It’s tricky to do a traditional case study on something that exists centuries in the future! But, we can create a hypothetical case study based on current trends and expert predictions about sustainable technology in 2690.

Hypothetical Case Study: The Integrated City of Aurora, 2690

Introduction:

The city of Aurora, in what was once Colorado, USA, stands as a model of sustainable urban living in 2690. Over centuries, it has transformed from a resource-intensive metropolis to a thriving, self-sufficient ecosystem powered by advanced sustainable technologies.

Challenges:

• Climate Change Impacts: By the 24th century, the effects of climate change were undeniable, with extreme weather events, rising sea levels, and disrupted ecosystems impacting the region.
• Resource Depletion: Finite resources like fossil fuels and certain minerals had become increasingly scarce and expensive.
• Population Growth: Aurora needed to accommodate a growing population while minimizing its environmental footprint.  

Solutions:

• Renewable Energy Integration: Aurora’s energy needs are met entirely by renewable sources. Solar panels are integrated into every building surface, and space-based solar collectors beam down energy from orbit. Fusion power plants provide a stable baseload energy supply.  
• Circular Economy Practices: Waste is virtually eliminated through advanced recycling and resource recovery systems. Products are designed for disassembly and reuse, creating a closed-loop system.
• Vertical Farming and Precision Agriculture: High-tech vertical farms within the city and AI-powered precision agriculture in surrounding areas provide abundant, locally sourced food with minimal land and water use.
• Smart City Infrastructure: Aurora is a “smart city” with interconnected systems that optimize energy use, transportation, and resource management. AI algorithms analyze data to improve efficiency and reduce environmental impact.  
• Sustainable Transportation: Electric vehicles, high-speed trains, and advanced air mobility systems provide efficient and low-emission transportation options.
• Green Buildings and Infrastructure: Buildings are designed to generate their own energy, collect rainwater, and have green spaces. The city’s infrastructure is designed to minimize environmental impact and enhance livability.

Results:

• Environmental Restoration: Aurora has achieved carbon neutrality and significantly reduced its environmental footprint.
• Resource Security: The city is no longer dependent on finite resources and has built resilient, self-sustaining systems.
• Economic Prosperity: Aurora has a thriving economy based on sustainable industries and innovation.
• High Quality of Life: Residents enjoy clean air and water, access to green spaces, and a high quality of life.

Lessons Learned:

• Long-Term Vision: The transformation of Aurora required a long-term vision and commitment to sustainability.
• Technological Innovation: Investing in research and development of sustainable technologies was crucial.
• Collaboration and Integration: Collaboration between governments, businesses, and individuals was essential to create integrated solutions.
• Adaptability and Resilience: The city needed to be adaptable to changing environmental conditions and resilient in the face of challenges.

Conclusion:

The case of Aurora demonstrates how sustainable technology, when implemented thoughtfully and comprehensively, can create thriving and resilient communities in the future. By prioritizing sustainability, we can ensure a healthy planet and a good quality of life for generations to come.

This is just one hypothetical example, of course. The specific technologies and solutions may differ, but the underlying principles of sustainability will b

COURTESY : NPTEL-NOC IITM

White paper on  Sustainable Technology of 2690  ?

White Paper: Envisioning Sustainable Technology in 2690

Abstract:

Predicting the precise nature of technology centuries into the future is an exercise in informed speculation. This white paper explores potential trajectories of sustainable technology in the year 2690, extrapolating from current trends, emerging innovations, and anticipated global challenges. It aims to stimulate discussion and inspire research and development towards a future where human civilization thrives in harmony with the planet.

1. Introduction:

The 27th century will inherit the consequences of choices made today. Climate change, resource depletion, and population growth necessitate a radical shift towards sustainable practices. This paper posits that by 2690, sustainable technology will not be a niche area but rather the foundation upon which all aspects of human civilization are built.

2. Key Areas of Focus:

This section outlines potential advancements in key areas of sustainable technology:

• 2.1 Energy: Fusion power, if realized, could provide near-limitless clean energy. Space-based solar farms and highly efficient, decentralized renewable energy systems will likely be commonplace. Advanced energy storage solutions will ensure grid stability and reliability.  
• 2.2 Resource Management: Circular economy principles will be deeply ingrained. Advanced material science could produce biodegradable or easily recyclable materials. AI-driven systems will optimize resource allocation and minimize waste. Nanotechnology might enable on-demand material creation and manipulation.  
• 2.3 Food Production: Vertical farms and precision agriculture, utilizing AI and robotics, will maximize food production with minimal land and water use. Genetically engineered crops will be more resilient and nutritious. Cultivated meat and other alternative protein sources could become mainstream.
• 2.4 Environmental Remediation: Direct air capture of carbon dioxide and advanced carbon sequestration technologies will be essential for mitigating climate change. Ocean cleanup and ecosystem restoration projects will be ongoing, potentially utilizing advanced biotechnology.
• 2.5 Transportation: Electric vehicles will dominate, powered by advanced batteries or alternative energy sources. Hyperloops, maglev trains, and potentially even personal air mobility systems could revolutionize transportation.
• 2.6 Built Environment: Buildings will be self-sufficient, generating their own energy, collecting and recycling water, and integrating with surrounding ecosystems. Smart city technologies will optimize resource use and improve quality of life.  
• 2.7 Information and Communication Technologies (ICT): Sustainable computing will be paramount. Data centers will be powered by renewable energy and utilize highly efficient cooling systems. Quantum computing, if realized, could offer unprecedented processing power with minimal energy consumption.  

3. Societal Implications:

The widespread adoption of sustainable technology in 2690 will have profound societal implications:

• Decentralization: Energy production, food production, and even manufacturing could become more decentralized, empowering local communities.
• Reduced Inequality: Access to resources and essential services could become more equitable, reducing disparities between nations and regions.
• Enhanced Quality of Life: Clean air and water, access to green spaces, and sustainable infrastructure will improve public health and well-being.
• Economic Transformation: New industries based on sustainable technologies will emerge, creating jobs and driving economic growth.
• Ethical Considerations: Advanced technologies like AI and genetic engineering raise ethical questions that will need careful consideration.  

4. Challenges and Opportunities:

Achieving this vision of a sustainable future presents significant challenges:

• Technological Development: Continued investment in research and development is crucial to realize the full potential of sustainable technologies.
• Global Collaboration: International cooperation is essential to address global challenges like climate change and resource depletion.  
• Behavioral Change: Shifting individual and societal behaviors towards sustainable practices is vital.
• Ethical Frameworks: Developing robust ethical frameworks for emerging technologies is crucial to ensure responsible innovation.

5. Conclusion:

The year 2690 represents a potential turning point in human history. By embracing sustainable technology and fostering a culture of environmental stewardship, we can create a future where humanity thrives in harmony with the planet. This requires concerted effort, innovation, and a long-term vision. The choices we make today will determine the world of tomorrow.

Disclaimer: This white paper presents a speculative vision of the future. The actual trajectory of technological development may differ. However, the underlying principles of sustainability remain crucial for ensuring a positive future for all.Sources and related content

Industrial application of  Sustainable Technology of 2690  ?

It’s fascinating to imagine the industrial applications of sustainable technology in 2690! Here are some potential scenarios, keeping in mind that this is speculative territory:

1. Advanced Manufacturing:

• On-demand production: Imagine factories that can produce any product, from clothing to electronics, using advanced 3D printing and nanotechnology. Raw materials would be sourced sustainably or even created on-site, minimizing transportation and waste.
• Closed-loop systems: Manufacturing processes would be entirely closed-loop, with all waste materials recycled or reused. Factories could even be integrated with ecosystems, with waste products used as nutrients for plants or other organisms.
• AI-powered optimization: AI algorithms would optimize every aspect of the manufacturing process, from design to production to distribution, minimizing energy use, resource consumption, and environmental impact.

2. Energy Production and Distribution:

• Decentralized energy grids: Energy production would be highly decentralized, with homes, factories, and even vehicles generating their own power from renewable sources. Smart grids would connect these distributed energy sources, ensuring a stable and reliable power supply.
• Fusion power plants: If nuclear fusion becomes a reality, it could provide a clean and nearly limitless source of energy for industrial processes.  
• Space-based solar: Solar energy could be collected in space and beamed down to Earth, providing a constant and abundant source of clean energy for industrial use.  

3. Resource Extraction and Processing:

• Sustainable mining: Mining operations would be highly automated and use advanced technologies to minimize environmental impact. Resources would be extracted with precision, and waste materials would be recycled or reused.
• Ocean mining: If necessary, ocean mining would be conducted sustainably, with minimal disruption to marine ecosystems.
• Material creation: Nanotechnology could potentially enable the creation of materials on demand, reducing the need for traditional mining altogether.

4. Agriculture and Food Production:

• Vertical farms: Vertical farms in urban areas would produce food with minimal land and water use, reducing transportation costs and environmental impact.  
• Precision agriculture: AI-powered systems would monitor crop health, soil conditions, and weather patterns, optimizing irrigation, fertilization, and pest control.  
• Cultivated meat: Cultivated meat and other alternative protein sources could become mainstream, reducing the environmental impact of traditional animal agriculture.

5. Environmental Remediation:

• Carbon capture and storage: Industrial facilities would capture their carbon emissions and store them safely, preventing them from entering the atmosphere.  
• Direct air capture: Technologies could capture carbon dioxide directly from the atmosphere, helping to reverse climate change.  
• Ecosystem restoration: Biotechnology could be used to restore damaged ecosystems and clean up pollution.

6. Transportation and Logistics:

• Electric vehicles: Electric vehicles would dominate the transportation sector, powered by clean energy sources.
• Hyperloops and maglev trains: High-speed transportation systems like hyperloops and maglev trains could revolutionize logistics, reducing transportation times and environmental impact.
• Autonomous vehicles: Self-driving vehicles could optimize logistics and reduce traffic congestion.  

These are just a few examples of how sustainable technology could be applied in industry in 2690. The possibilities are vast, and the specific technologies and solutions will depend on the challenges and opportunities that arise in the coming centuries. However, the underlying principle remains the same: to create a world where human industry thrives in harmony with the planet.Sources and related content

Research and development of  Sustainable Technology of 2690  ?

It’s exciting to think about the kind of research and development that might lead to the sustainable technologies of 2690! Here’s a glimpse into potential areas of focus, keeping in mind this is highly speculative:

1. Advanced Materials Science:

• Biodegradable super-materials: Imagine materials with the strength and durability of current materials, but that can completely biodegrade on demand or be easily recycled.
• Self-healing materials: Materials that can repair themselves when damaged, extending their lifespan and reducing waste.  
• Adaptive materials: Materials that can change their properties in response to environmental stimuli, such as temperature or light.  
• Nanomaterials for targeted applications: Developing nanomaterials with specific properties for use in various applications, from energy storage to environmental remediation.

2. Energy Generation and Storage:

• Fusion power breakthroughs: Continued research into nuclear fusion, aiming to achieve a stable and efficient fusion reactor.
• Exotic energy sources: Exploring unconventional energy sources, such as zero-point energy or tapping into geothermal energy from deep within the Earth.
• Advanced energy storage: Developing batteries or other energy storage solutions with vastly higher energy density, faster charging times, and longer lifespans.
• Wireless energy transfer: Technologies that can transmit energy wirelessly over long distances, enabling more efficient energy distribution.

3. Biotechnology and Agriculture:

• Enhanced photosynthesis: Engineering crops with significantly higher photosynthetic efficiency, increasing yields and reducing the need for land and resources.
• Nitrogen fixation: Developing crops that can fix nitrogen from the air, reducing the need for fertilizers.
• Disease-resistant crops: Engineering crops that are resistant to pests and diseases, reducing the need for pesticides.  
• Cultivated meat and alternative proteins: Developing more efficient and sustainable methods for producing cultivated meat and other alternative protein sources.

4. Environmental Remediation:

• Direct air capture of CO2: Improving the efficiency and scalability of direct air capture technologies to remove carbon dioxide from the atmosphere.
• Carbon mineralization: Developing methods to convert captured carbon dioxide into stable minerals for long-term storage.  
• Ocean cleanup technologies: Developing advanced technologies for removing plastic and other pollutants from the oceans.
• Ecosystem restoration: Using biotechnology and other techniques to restore damaged ecosystems and enhance biodiversity.

5. Artificial Intelligence and Robotics:

• AI for sustainability: Developing AI algorithms that can optimize resource use, predict environmental changes, and design new sustainable technologies.
• Autonomous systems: Creating robots and other autonomous systems for use in sustainable agriculture, manufacturing, and environmental remediation.  
• Human-computer interfaces: Developing advanced interfaces that allow humans to interact more effectively with technology and control complex sustainable systems.

6. Space-Based Technologies:

• Space-based solar power: Developing large-scale solar farms in space to collect solar energy and beam it down to Earth.
• Resource extraction from space: Exploring the possibility of sustainably extracting resources from asteroids or other celestial bodies.  
• Space-based manufacturing: Developing technologies for manufacturing products in space, potentially reducing the need for resource extraction on Earth.

7. Social and Ethical Considerations:

• Sustainable development pathways: Researching and modeling different pathways to achieve a sustainable future, considering social, economic, and environmental factors.
• Ethical frameworks for technology: Developing ethical guidelines and regulations for the use of advanced technologies, ensuring they are used responsibly and for the benefit of humanity.
• Public engagement: Engaging the public in discussions about sustainable technology and its implications, fostering a shared vision for the future.

It’s important to remember that these are just a few possibilities. The actual direction of research and development will depend

COURTESY : Accenture

Reference

• Beder, S. (1997). Global Spin: The Corporate Assault on Environmentalism. Green Books.
• Beder, S. (2000). Global Spin: The Corporate Assault on Environmentalism. Green Books.
• Belz, F.-M.; Peattie, K. (2009). Sustainability Marketing. A global perspective (1st ed.). Glasgow: John Wiley & Sons.
• Bentley, M. (2004). “Tracking Progress: implementing sustainable consumption policies”. A global review of implementation of the United Nations Guidelines for Consumer Protection (2nd ed.). UNEP and Consumers International.
• Bolls, Paul D.; Muehling, Darrel D. (2007). “The Effects of Dual-Task Processing on Consumers’ Responses to High- and Low-Imagery Radio Advertisements”. Journal of Advertising. 36 (4): 35–47. doi:10.2753/JOA0091-3367360403. S2CID 143523914.
• Dennis, E.E. (1991). “In context: environmentalism in the system of news”. Media and the Environment. Washington: Island Press. pp. 55–64.
• Dollt, Andreas, ed. (2003). Cinema, TV and radio in the EU – Statistics on audiovisual services – Data 1980–2002. Luxembourg: Office for Official Publications of the European Communities. ISBN 92-894-5709-0. ISSN 1725-4515. Retrieved 2022-10-22.
• Earthprint publishing (2007). Sustainability Communications: A Toolkit for Marketing and Advertising Courses.^{[full citation needed]}
• Gronroos, C. (1999). “Relationship marketing: Challenges for the organization”. Journal of Business Research. 46 (3). doi:10.1016/S0148-2963(98)00030-7.
• Gronroos, C. (1994). “From Marketing Mix to Relationship Marketing:Towards a Paradigm Shift in Marketing”. Management Decision. 32 (2). doi:10.1108/00251749410054774. hdl:11323/385.
• Jackson, T. (2005). Motivating sustainable consumption: a review of evidence on consumer behavior and behavioral change. Centre for Environmental Strategy. University of Surrey.
• Kilbourne, William E. (2004). “Sustainable communication and the dominant social paradigm: can they be integrated?”. Marketing Theory. 4 (3): 187–208. doi:10.1177/1470593104045536. S2CID 154778630.
• Kolandai-Matchett, K. (2009). “Mediated communication of ‘sustainable consumption’ in the alternative media: a case study exploring a message framing strategy”. International Journal of Consumer Studies. 33 (2): 113–125. doi:10.1111/j.1470-6431.2009.00754.x.
• Krugman, H.E. (1965). “The impact of television advertising: learning without involvement”. The Public Opinion Quarterly. 29 (3): 349–356. doi:10.1086/267335.
• Laufer, W.S. (2003). “Social Accountability and Corporate Greenwashing”. Journal of Business Ethics. 43.
• Lichtl, M. (1999). Ecotainment: Der neue Weg im Umweltmarketing. Wien, Frankfurt.
• Longhurst, M. (July–August 2003). “Advertising and sustainability: a new paradigm”. Admap.
• Lovell, C. (8 May 2004). “Is sustainability an advertising issue?”. Campaign.
• McCarthy, E.J. (1960). Basic Marketing. Homewood, IL: Irwin.
• Michaelis, L. (2001). The Media: A Resource for Sustainable Consumption. Oxford: Oxford Centre for the Environment, Ethics & Society.
• Munshi, D.; Kurian, P. (2005). “Imperializing spin cycles: A postcolonial look at public relations, greenwashing, and the separation of publics”. Public Relations Review. 31 (4): 513. doi:10.1016/j.pubrev.2005.08.010.
• Pavlou, P.A.; Stewart, D.W. (2000). “Measuring the Effects and Effectiveness of Interactive Advertising: A Research Agenda”. Journal of Interactive Advertising. doi:10.1080/15252019.2000.10722044. S2CID 168153520. Archived from the original on 2011-07-26.
• Sandman, P. (1974). “Mass environmental education: can the media do the job?”. In Swan, J.A.; Stapp W.B. (eds.). Environmental Education: Strategies Toward a More Livable Future. New York: Sage Publications, Inc. pp. 207–247.
• Sander, Frauke; Fohl, Ulrich; Walter, Nadine (25 March 2021). “Green or social? An analysis of environmental and social sustainability advertising and its impact on brand personality, credibility and attitude”. Journal of Brand Management. 28 (4): 429–445. doi:10.1057/s41262-021-00236-8. hdl:10419/287669. S2CID 233676078.
• Schrader, Ulf (2005). “Von der Öko-Werbung zur Nachhaltigkeits-Kommunikation”. In Belz, F.-M.; Bilharz, M. (eds.). Nachhaltigkeits-Marketing in Theorie und Praxis. pp. 61–74.
• Shabbir, Muhammad; Sulaiman, Mohammed; Al-Kumaim, Nabil; Mahmood, Arshad; Abbas, Mazhar (29 October 2020). “Green Marketing Approaches and Their Impact on Consumer Behavior towards the Environment—A study from the UAE”. Sustainability. 12 (21): 2–8. doi:10.3390/su12218977.
• Shanahan, J. (1996). “Green but unseen: marginalizing the environment on television”. In Morgan, M.; Leggett, S. (eds.). Margin(s) and Mainstreams: Cultural Politics in the 90s. Westport, CT: Greenwood Press. pp. 176–193.
• United Nations Environment Programme (UNEP); World Federation of Advertisers (WFA); European Association of Communications Agencies (EACA) (2002). Industry as a partner for sustainable development: Advertising. United Nations Environment Programme.
• United Nations Environment Programme – UNEP (2007). Sustainability Communications. A Toolkit for Marketing and Advertising Courses. Division for Technology, Industry and Economics.