Sustainable Technology of 2370

Sustainable Technology of 2370 ?

Sustainable technology in 2370 could be vastly different from what we see today. Here are some potential advancements:

• Advanced Energy Systems: Fusion power or other highly efficient, clean energy sources could be commonplace, powering cities and industries with minimal environmental impact.
• Closed-Loop Resource Systems: Technologies for complete recycling and reuse of materials could eliminate waste and pollution, creating a circular economy.
• Hyper-Efficient Transportation: Maglev trains, hypersonic air travel, or even personal transportation systems could be powered by sustainable energy sources, reducing travel time and emissions.
• Vertical Farms and Lab-Grown Food: Food production could take place in urban centers using vertical farms and lab-grown meat, reducing the need for land and transportation.
• Climate Engineering: Technologies to safely manage the Earth’s climate might be in use to counteract the effects of past pollution.
• Smart Infrastructure: Cities could be managed by AI systems that optimize energy use, traffic flow, and resource allocation for maximum sustainability.

It’s important to remember that this is just speculation. The actual sustainable technologies of 2370 could be very different depending on how society evolves and the challenges we face.

What is Sustainable Technology of 2370 ?

Sustainable technology in 2370 is a fascinating topic to speculate about! It’s likely to be far more advanced than what we have today, driven by the need to address climate change and resource limitations. Here are some possibilities:

• Energy:
  • Fusion Power: Perhaps by 2370, fusion energy will be a practical and widespread reality, providing clean and abundant power.
  • Space-Based Solar: Imagine massive solar arrays in space beaming energy back to Earth, providing a constant and reliable source of renewable energy.
  • Advanced Energy Storage: Highly efficient and compact energy storage solutions could be developed, allowing for easy storage and distribution of renewable energy.
• Resource Management:
  • Closed-Loop Recycling: Technologies that can break down materials into their basic components and reuse them endlessly could become commonplace, eliminating waste.
  • Resource Extraction from Waste: Advanced systems might be able to extract valuable resources from waste materials, turning trash into treasure.
  • Sustainable Materials: New, biodegradable, and highly durable materials could be developed, reducing our reliance on finite resources.
• Food Production:
  • Vertical Farms: Multi-story, high-tech farms in urban areas could produce food locally, reducing transportation needs and land use.
  • Lab-Grown Food: Meat and other food products could be grown in labs, reducing the need for traditional agriculture and its environmental impact.
  • Personalized Nutrition: Advanced technologies could analyze an individual’s needs and create customized food products, optimizing health and reducing waste.  
• Transportation:
  • Maglev Trains: High-speed maglev trains could connect cities and regions, providing efficient and low-emission transportation.
  • Hypersonic Travel: Air travel could become much faster and more efficient, with hypersonic planes powered by sustainable fuels.
  • Personal Air Vehicles: Perhaps personal flying vehicles powered by clean energy sources could become a reality, transforming urban transportation.
• Environment:
  • Climate Engineering: Technologies to safely manage the Earth’s climate might be in use to counteract the effects of past pollution.
  • Ocean Cleanup: Advanced systems could be deployed to remove plastic and other pollutants from the oceans, restoring marine ecosystems.
  • Reforestation and Habitat Restoration: Technologies could be used to efficiently restore forests and other natural habitats, increasing biodiversity and carbon sequestration.  
• Infrastructure:
  • Smart Cities: Cities could be managed by AI systems that optimize energy use, traffic flow, and resource allocation for maximum sustainability.  
  • Self-Healing Infrastructure: Materials that can repair themselves could be used in buildings and infrastructure, reducing maintenance needs and extending lifespan.
  • 3D-Printed Housing: On-demand 3D printing could be used to create affordable and sustainable housing, reducing construction waste and costs.  

These are just a few possibilities, and the actual sustainable technologies of 2370 could be very different. It’s exciting to imagine the advancements that could be made in the next 150 years!Sources and related content

Who is required Sustainable Technology of 2370 ?

It’s not a question of who requires sustainable technology in 2370, but rather that everyone will likely depend on it for their survival and well-being. Here’s why:

• Resource Scarcity: By 2370, we may have depleted many of the Earth’s easily accessible resources. Sustainable technologies will be crucial for efficiently managing remaining resources and finding alternatives.
• Climate Change Impacts: The effects of climate change are likely to worsen in the coming centuries. Sustainable technologies will be needed to mitigate these effects, adapt to changing conditions, and potentially even reverse some of the damage.  
• Population Growth: The global population is expected to continue growing. Sustainable technologies will be essential for providing food, water, energy, and shelter for everyone in a way that doesn’t further strain the planet’s resources.
• Environmental Degradation: Pollution, deforestation, and other forms of environmental degradation will need to be addressed. Sustainable technologies can help to clean up the environment, restore ecosystems, and prevent further damage.  

In short, sustainable technology in 2370 will be necessary for:

• Individuals: To have access to basic necessities like food, water, and energy, and to live healthy and fulfilling lives.
• Communities: To thrive and prosper in a way that doesn’t harm the environment or future generations.
• The Planet: To maintain its ability to support life and provide the resources we need.

It’s not just about having a better quality of life, but about ensuring the very survival of humanity and the health of our planet.Sources and related content

When is required Sustainable Technology of 2370 ?

While the need for sustainable technology in 2370 is clear, the question of when it’s required is more nuanced. It’s not a single point in time, but rather an ongoing process that starts now and continues indefinitely. Here’s why:

• Gradual Implementation: Sustainable technologies won’t magically appear in 2370. They need to be developed, tested, and implemented over time. This process starts today with research, innovation, and policy changes.
• Urgency of Climate Change: The effects of climate change are already being felt, and they will worsen in the coming decades. We need to adopt sustainable technologies as quickly as possible to mitigate these effects and prevent further damage.  
• Resource Depletion: Many of the Earth’s resources are finite. We need to start using them more efficiently and finding alternatives now to ensure that there are enough resources left for future generations.  
• Continuous Improvement: Sustainable technology is not a static concept. It will need to evolve and improve over time as new challenges arise and new discoveries are made. This requires ongoing research and development.  

Therefore, the answer to “when” is:

• As soon as possible: We need to accelerate the development and adoption of sustainable technologies to address the urgent challenges we face.
• Continuously: Sustainability is not a destination, but a journey. We need to constantly strive to improve our technologies and practices to ensure a sustainable future.  

In essence, the need for sustainable technology in 2370 is a direct consequence of the choices we make today. The sooner we prioritize sustainability, the better equipped we will be to face the challenges of the future.

courtesy : Bernard Marr

Where ia required Sustainable Technology of 2370 ?

Sustainable technology in 2370 will be required everywhere. It won’t be limited to specific locations or industries. Here’s a breakdown of where it will be essential:

• Urban Centers: Cities will rely on sustainable technologies for energy-efficient buildings, transportation systems, waste management, and resource optimization.  
• Rural Areas: Sustainable agriculture, renewable energy generation, and efficient water management will be crucial for food production and rural development.
• Industrial Zones: Industries will need to adopt sustainable technologies to minimize their environmental impact, reduce waste, and utilize resources efficiently.
• Transportation Networks: Sustainable fuels, efficient vehicles, and smart traffic management systems will be needed for land, air, and sea travel.
• Homes and Buildings: Sustainable building materials, energy-efficient appliances, and smart home systems will be essential for reducing energy consumption and promoting sustainable living.
• Infrastructure: Sustainable materials, self-healing systems, and smart grids will be needed for roads, bridges, power plants, and other infrastructure.
• Natural Environments: Sustainable technologies will be required to protect and restore ecosystems, manage wildlife populations, and prevent pollution.
• Space: As humanity expands beyond Earth, sustainable technologies will be crucial for space exploration, resource utilization, and establishing off-world settlements.

Essentially, sustainable technology in 2370 will be integrated into every aspect of human life and activity. It will be the foundation of a healthy and thriving society that lives in harmony with the planet.

It’s important to remember that this is not just about having fancy gadgets or futuristic solutions. It’s about creating a way of life that can be sustained for generations to come.

How is required Sustainable Technology of 2370 ?

That’s a great question! It’s not just about having sustainable technology in 2370, but how it’s integrated and used that will truly matter. Here’s how sustainable technology will likely be required in 2370:

1. Proactive Development and Implementation:

• Continuous Research and Innovation: Sustainable technology won’t just appear overnight. It will require ongoing research, development, and testing to create new solutions and improve existing ones.
• Global Collaboration: Addressing climate change and resource scarcity will require international cooperation and knowledge sharing to develop and implement sustainable technologies effectively.
• Policy and Regulation: Governments will need to play a role in creating policies and regulations that incentivize the development and adoption of sustainable technologies.

2. Integration into All Aspects of Life:

• Seamless Integration: Sustainable technology won’t be separate from everyday life; it will be seamlessly integrated into homes, workplaces, transportation systems, and infrastructure.
• Accessibility and Affordability: Sustainable technologies will need to be accessible and affordable for everyone, not just the wealthy, to ensure equitable access to resources and a sustainable future for all.
• Behavioral Changes: Sustainable technology will need to be accompanied by changes in human behavior, such as reducing consumption, adopting more sustainable lifestyles, and valuing environmental stewardship.

3. Adaptive and Resilient Systems:

• Flexibility and Adaptability: Sustainable technologies will need to be flexible and adaptable to changing conditions, such as climate change impacts and resource availability.
• Resilience: Sustainable systems will need to be resilient to shocks and disruptions, such as natural disasters or technological failures.
• Long-Term Thinking: Sustainable technology will require a long-term perspective, considering the needs of future generations and the health of the planet.

In essence, sustainable technology in 2370 will be required through:

• Proactive and continuous effort: It’s not a one-time fix, but an ongoing process of innovation and improvement.
• Holistic integration: It needs to be woven into every aspect of how we live and interact with the world.
• Adaptive and resilient design: It must be able to withstand challenges and adapt to changing circumstances.

Ultimately, how sustainable technology is required in 2370 will depend on the choices we make today. The sooner we prioritize sustainability and invest in developing and implementing sustainable technologies, the better equipped we will be to create a thriving and sustainable future for all.

You stopped this response

Case study is Sustainable Technology of 2370 ?

It’s impossible to provide a real case study of sustainable technology in 2370, as that’s far in the future. However, we can create a hypothetical case study based on the trends and possibilities we’ve discussed. This allows us to explore how such technologies might function and interact.

Hypothetical Case Study: The Eco-City of Aurora, 2370

Context: By 2370, coastal cities are facing significant challenges due to rising sea levels and extreme weather events. Aurora, a city built on reclaimed land in what was once a coastal region, has become a model of sustainable urban living.

Sustainable Technologies in Action:

• Energy: Aurora is powered entirely by a network of space-based solar power stations. Energy is beamed down to the city and stored in highly efficient, compact energy storage units. Smart grids optimize energy distribution based on real-time needs, minimizing waste.  
• Resource Management: Aurora operates on a closed-loop resource system. Advanced recycling plants break down all waste materials into their basic components, which are then reused to create new products. Resource extraction from old landfills and other waste sites has become a major industry.  
• Food Production: Vertical farms within the city produce a significant portion of Aurora’s food. These high-tech farms use hydroponics and aeroponics to grow crops efficiently, minimizing water and land use. Lab-grown meat and personalized nutrition systems supplement local food production.
• Transportation: Personal air vehicles (PAVs) powered by clean energy sources are the primary mode of transportation within Aurora. These PAVs operate on designated air corridors, minimizing congestion and noise pollution. High-speed maglev trains connect Aurora to other cities and regions.
• Water Management: Aurora has a sophisticated water recycling and purification system. All wastewater is treated and reused for irrigation and other non-potable purposes. Atmospheric water generators capture moisture from the air to supplement water supplies.  
• Infrastructure: Aurora’s buildings are constructed from self-healing, biodegradable materials. Smart building management systems optimize energy use, lighting, and ventilation based on occupancy and environmental conditions. 3D printing is used to create customized housing and infrastructure components on demand.  
• Environment: Aurora has invested heavily in restoring and protecting its surrounding ecosystems. Advanced ocean cleanup technologies have removed plastic and other pollutants from the nearby waters. Reforestation projects have increased biodiversity and carbon sequestration.

Outcomes:

• Environmental Sustainability: Aurora has a minimal carbon footprint and operates in harmony with its surrounding environment.
• Resource Efficiency: The city’s closed-loop resource system minimizes waste and maximizes resource utilization.
• Economic Prosperity: Aurora has a thriving economy based on sustainable industries and technologies.
• Social Equity: All residents of Aurora have access to clean energy, safe housing, and nutritious food.
• Resilience: Aurora is well-prepared to withstand the impacts of climate change and other environmental challenges.

Lessons Learned (Hypothetical):

• Long-term planning and investment are essential for creating sustainable cities.
• Technological innovation is crucial, but it must be accompanied by behavioral changes and policy support.
• Collaboration between governments, businesses, and individuals is necessary to achieve sustainability goals.

This hypothetical case study illustrates how a combination of advanced technologies, smart planning, and societal commitment could create a truly sustainable city in the future. While the specific technologies may differ, the underlying principles of resource efficiency, environmental protection, and social equity will remain essential for creating a sustainable future for all.Sources and related content

courtesy : Accenture

White paper on Sustainable Technology of 2370 ?

White Paper: Sustainable Technology in 2370: A Vision for a Thriving Future

Abstract:

This white paper explores potential advancements in sustainable technology by the year 2370, considering the urgent need to address climate change, resource depletion, and population growth. It outlines a vision for a future where technology enables a harmonious relationship between humanity and the planet, focusing on key areas like energy, resource management, food production, transportation, environment, and infrastructure. This paper aims to stimulate discussion and inspire innovation towards a sustainable future.

1. Introduction:

The challenges facing humanity in the 21st century, including climate change, resource scarcity, and environmental degradation, necessitate a fundamental shift towards sustainable practices. By 2370, it is envisioned that sustainable technologies will be deeply integrated into every aspect of human life, ensuring a thriving future for generations to come. This paper explores potential technological advancements across key sectors.

2. Energy:

• Fusion Power: Practical and commercially viable fusion energy is anticipated to be a primary energy source, providing clean, abundant, and safe power.
• Space-Based Solar: Large-scale solar arrays in orbit collect solar energy and beam it back to Earth, providing a continuous and reliable source of renewable energy.  
• Advanced Energy Storage: Highly efficient and compact energy storage solutions allow for the seamless integration of intermittent renewable energy sources and enable decentralized energy systems.  

3. Resource Management:

• Closed-Loop Recycling: Advanced recycling technologies break down materials into their constituent components, allowing for the complete reuse of resources and eliminating waste.  
• Resource Extraction from Waste: Technologies are developed to efficiently extract valuable resources from existing waste streams, turning waste into a valuable resource.  
• Sustainable Materials: Biodegradable, durable, and high-performance materials are developed, reducing reliance on finite resources and minimizing environmental impact.

4. Food Production:

• Vertical Farms: Urban-based vertical farms utilizing hydroponics and aeroponics maximize food production while minimizing land and water use.  
• Lab-Grown Food: Cultivated meat and other food products are produced in laboratories, reducing the environmental impact of traditional agriculture.  
• Personalized Nutrition: Advanced diagnostics and food synthesis technologies enable personalized nutrition plans and on-demand food production tailored to individual needs.

5. Transportation:

• Maglev Trains: High-speed maglev trains connect cities and regions, providing efficient and low-emission transportation for people and goods.  
• Hypersonic Travel: Sustainable-fueled hypersonic aircraft enable rapid global travel with minimal environmental impact.
• Personal Air Vehicles (PAVs): Clean-energy powered PAVs provide efficient and personalized urban transportation, reducing congestion and emissions.

6. Environment:

• Climate Engineering: Technologies for safely managing the Earth’s climate are developed and deployed to mitigate the effects of past pollution and stabilize the climate.
• Ocean Cleanup: Advanced robotic systems and bioremediation techniques are used to remove plastic and other pollutants from the oceans, restoring marine ecosystems.  
• Ecosystem Restoration: Technologies are developed to efficiently restore degraded ecosystems, including forests, wetlands, and coral reefs.

7. Infrastructure:

• Smart Cities: AI-powered smart city systems optimize energy use, traffic flow, resource allocation, and infrastructure management for maximum efficiency and sustainability.  
• Self-Healing Infrastructure: Buildings and infrastructure are constructed from self-healing materials that can repair themselves, reducing maintenance needs and extending lifespan.
• 3D-Printed Housing: On-demand 3D printing enables the rapid and cost-effective construction of sustainable housing using locally sourced materials.  

8. Social and Ethical Considerations:

• Equitable Access: Ensuring equitable access to sustainable technologies and resources for all members of society is crucial.
• Ethical Development: Sustainable technology development must be guided by ethical principles, considering the potential social and environmental impacts.  
• Global Cooperation: International collaboration and knowledge sharing are essential for addressing global sustainability challenges.

9. Conclusion:

The vision of a sustainable future in 2370 requires a concerted effort from scientists, engineers, policymakers, and individuals alike. By investing in research, fostering innovation, and embracing sustainable practices, we can create a world where technology empowers humanity to live in harmony with the planet, ensuring a thriving future for all. This white paper serves as a starting point for further discussion and exploration of the path towards a sustainable tomorrow.Sources and related content

Industrial application of Sustainable Technology of 2370 ?

You’re right to ask about industrial applications! Sustainable technology in 2370 won’t just be for homes and transportation; it will revolutionize industries. Here are some potential applications:

1. Manufacturing:

• Closed-Loop Production: Factories will operate on closed-loop systems, where all waste materials are recycled and reused within the production process. This eliminates waste and reduces the need for raw materials.  
• On-Demand Manufacturing: 3D printing and other advanced manufacturing technologies will enable the production of goods on demand, reducing overproduction and waste.  
• Sustainable Materials: Industries will use biodegradable, durable, and high-performance materials derived from renewable resources or recycled materials.
• AI-Powered Optimization: AI systems will optimize production processes for energy efficiency, resource utilization, and minimal environmental impact.  

2. Resource Extraction:

• Sustainable Mining: Advanced technologies will be used to extract resources with minimal environmental impact, reducing habitat destruction and pollution.
• Resource Recovery: Industries will focus on recovering valuable materials from waste streams, turning trash into treasure.
• Alternative Resources: Research and development will focus on finding and utilizing alternative resources to reduce reliance on finite materials.

3. Agriculture:

• Precision Farming: Advanced sensors, robotics, and AI will be used to optimize crop yields while minimizing water and fertilizer use.  
• Vertical Farming: Large-scale vertical farms will be integrated into urban areas, providing fresh produce locally and reducing transportation needs.  
• Sustainable Aquaculture: Technologies will be developed to raise fish and other seafood in a sustainable way, reducing pressure on wild populations.

4. Construction:

• Sustainable Building Materials: Buildings will be constructed from biodegradable, self-healing materials that minimize environmental impact.
• Modular Construction: Prefabricated and modular building components will be used to reduce construction waste and improve energy efficiency.  
• Smart Buildings: Buildings will be equipped with AI systems that optimize energy use, lighting, and ventilation based on occupancy and environmental conditions.  

5. Energy Production:

• Fusion Power Plants: Fusion energy will provide a clean and abundant source of power for industrial processes.
• Renewable Energy Integration: Industries will rely on a mix of renewable energy sources, such as solar, wind, and geothermal, integrated with advanced energy storage systems.
• Energy Efficiency: Industries will implement energy-efficient technologies and processes to minimize energy consumption.

6. Waste Management:

• Advanced Recycling: Recycling plants will be able to break down complex materials into their basic components for reuse.
• Waste-to-Energy: Technologies will be used to convert waste into energy, reducing landfill waste and generating clean power.
• Composting and Biogas: Organic waste will be composted or used to generate biogas, a renewable energy source.

7. Water Management:

• Water Recycling: Industries will implement closed-loop water systems, where wastewater is treated and reused for industrial processes.
• Desalination: Advanced desalination technologies will be used to provide fresh water for industrial use in water-scarce regions.
• Water Efficiency: Industries will implement water-efficient technologies and processes to minimize water consumption.  

These are just a few examples of how sustainable technology could be applied in industries by 2370. The key is that sustainability will be integrated into every aspect of industrial activity, from resource extraction to manufacturing to waste management. This will create a more circular and environmentally responsible industrial system.

Research and development of Sustainable Technology of 2370 ?

You’re thinking ahead! Research and development (R&D) for sustainable technology in 2370 is a crucial topic. Here’s how it might look:

1. Fundamental Scientific Research:

• Materials Science: Discovering and developing new materials with unique properties, like self-healing polymers, advanced biodegradable plastics, or materials with near-perfect energy conductivity.
• Energy Physics: Investigating new energy sources beyond fusion, perhaps tapping into zero-point energy or other theoretical concepts.
• Biological Engineering: Developing advanced bio-integrated technologies that can be used for environmental cleanup, resource production, or even climate engineering.
• Cognitive Science: Understanding how humans interact with technology to design systems that are both efficient and user-friendly, promoting sustainable behaviors.  

2. Engineering and Technology Development:

• Advanced Manufacturing: Perfecting 3D printing at the nanoscale, enabling the creation of complex and highly efficient devices and systems.
• AI and Machine Learning: Developing sophisticated AI systems that can manage complex infrastructure, optimize resource allocation, and even predict and mitigate environmental disasters.
• Nanotechnology: Manipulating matter at the atomic and molecular level to create new materials, devices, and processes with unprecedented capabilities.  
• Space Technology: Investing in space-based infrastructure for energy collection, resource extraction, and even climate management.

3. Interdisciplinary Collaboration:

• Cross-Disciplinary Teams: Researchers from various fields, including science, engineering, social sciences, and even the arts, will work together to tackle complex sustainability challenges.
• Global Knowledge Sharing: International collaboration and open-source research will be essential for accelerating the development and dissemination of sustainable technologies.
• Citizen Science: Engaging the public in research and data collection can provide valuable insights and accelerate the pace of innovation.  

4. Ethical Considerations:

• Responsible Innovation: R&D will need to be guided by ethical principles, considering the potential social and environmental impacts of new technologies.  
• Risk Assessment: Thoroughly evaluating the risks and unintended consequences of new technologies before widespread implementation.
• Public Dialogue: Engaging in open and transparent discussions about the ethical implications of sustainable technologies and ensuring public input into decision-making.

5. Future-Oriented Thinking:

• Long-Term Vision: R&D will need to focus on long-term sustainability goals, considering the needs of future generations and the health of the planet.
• Scenario Planning: Developing models and simulations to explore different future scenarios and identify the most promising pathways for sustainable development.
• Adaptive Research: Continuously adapting research priorities and strategies based on new discoveries, emerging challenges, and evolving societal needs.

In essence, R&D for sustainable technology in 2370 will be:

• Driven by fundamental scientific inquiry: Exploring the frontiers of knowledge to unlock new possibilities.
• Focused on engineering and technological advancements: Translating scientific discoveries into practical solutions.
• Highly collaborative and interdisciplinary: Bringing together diverse perspectives and expertise.
• Guided by ethical considerations: Ensuring responsible innovation and minimizing risks.
• Future-oriented and adaptive: Anticipating future challenges and adapting to changing conditions.

By investing in this type of forward-thinking and comprehensive research and development, we can pave the way for a truly sustainable future in 2370 and beyond.

courtesy : NPTEL-NOC IITM

References

1. ^ “about”. www.csus.edu. Retrieved 2016-04-04.
2. ^ “about”. www.csus.edu. Retrieved 2016-04-04.
3. ^ “A Multi-Trophic Sustainable Food Production System Integrating Aquaponics and Bio-Waste Recycling| Research Project Database | NCER | ORD | US EPA”. cfpub.epa.gov. Retrieved 2016-05-08.
4. ^ “Epicure Catering at Sacramento State”. www.dining.csus.edu. Retrieved 2016-05-08.
5. ^ “Dining Commons”. www.dining.csus.edu. Retrieved 2016-05-08.
6. ^ “A Multi-Trophic Sustainable Food Production System Integrating Aquaponics and Bio-Waste Recycling”. cfpub.epa.gov. Retrieved 2016-05-31.
7. ^ “A Multi-Trophic Sustainable Food Production System Integrating Aquaponics and Bio-Waste Recycling| Research Project Database | NCER | ORD | US EPA”. cfpub.epa.gov. Retrieved 2016-05-08.
8. ^ “aquaponics”. www.csus.edu. Retrieved 2016-04-04.
9. ^ “Sac State Continues Tradition of a Green Campus” (Press release).
10. ^ Biodiesel Benefits and Considerations
11. ^ Environmental, economic, and energetic costs and benefits of biodiesel and ethanol biofuels
12. ^ Jump up to:^a b Comparison of the performance and emissions of different biodiesel blends against petroleum diesel
13. ^ Vermiculture, STORC
14. ^ “CORNELL Composting – Compost Microorganisms”. compost.css.cornell.edu. Retrieved 2016-05-09.
15. ^ “How Composting Works”. HowStuffWorks. 2001-04-02. Retrieved 2016-05-09.
16. ^ Moyle, Peter (2002). Inland Fishes of California. Berkeley: University of California Press.
17. ^ Miller, Chris (2011). “Preliminary Report on Feed Trials of Sacramento Perch” (PDF). Fisheries Science.
18. ^ Tilman, David; Balzer, Christian; Hill, Jason; Befort, Belinda L. (2011-12-13). “Global food demand and the sustainable intensification of agriculture”. Proceedings of the National Academy of Sciences. 108 (50): 20260–20264. doi:10.1073/pnas.1116437108. ISSN 0027-8424. PMC 3250154. PMID 22106295.