Jharkhand Aims to Boost Irrigation Coverage

CM Champai Soren Pushes for Modern Irrigation Technologies The Jharkhand government is intensifying efforts to expand irrigation facilities, with a focus on innovative solutions to reach every farm in the state. RANCHI – Chief Minister Champai Soren conducted a high-level review meeting of the Water Resources Department, emphasizing the need to accelerate irrigation projects across…

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I really hope they can work the bugs out of this solution, because if it's done right, it'll really be a win-win situation. Less evaporation of water, and solar power being generated every day? Yes, please. We are smart, resourceful beings, and this is far from the most difficult problem we've had to address.

This is also a great example of how we can go back and fix mistakes of the past. We very, very rarely ever come up with technological solutions that take long-term effects on the environment into consideration, and so the way many things are designed often leads to some sort of damage, whether through manufacture, use, disposal, or all of the above. Retrofitting canals (which have been used in agriculture for thousands of years) will have benefits not only in the ways mentioned above, but also gets people thinking more about the impacts we make.

I'm hoping that this will lead to more new technology being developed in ways that already anticipate and account for negative impacts so that they avoid them in the first place, rather than having to engineer new solution many years down the line.

“If we used to use oil-powered machines to flow water from irrigation canals to your fields, now we power it with electricity from sunlight. Free electricity from the sun so we can provide free irrigation,” said Marcos Jr at the inauguration ceremony. “Certainly because of the construction of this solar-powered pump irrigation project, in your barangay there will be a continuous flow of water in the irrigation systems, crops will be well taken care of, your harvests will increase, double to the product.” 

The project is the first in the Philippines to be constructed over an irrigation canal, meaning that the land cultivated by farmers will not be reduced.

sometimes you just have to be grateful for the little things (the shirt you bought from your local leftist org being dropped off before your Amazon package so they don’t see you being a bad leftist)

Learn how solar water pump for hydroponics provide eco-friendly, efficient irrigation solutions. Discover their benefits and how they simplify plant water management.

Global Greening Deserts Projects for Desalination, Energy Storage and Hydrogen Production

As many people know the integration of solar, water and wind energy is essential for sustainable living, production and working future. Everyone should consider how these solutions can be tailored to fit various contexts and address specific regional challenges – especially efficient and intelligent energy consumption and energy storage. By adapting technologies and strategies to meet local needs, we can maximize the impact and sustainability of renewable energy initiatives. Global Greening Deserts project developer have been developing world-leading concepts and projects for many years. Agrovoltaik, Energy Storage Park, Greenhouse Ship, Greening Camps and RecyclingShip are some of the flagship projects. Urban Greening Camps are another outstanding large-scale developments, especially for megacities and regions that need better, faster and more efficient greening or re-greening. Solar cities with more water storage capacity through sponge city concepts, brighter and greener spaces, modular and mobile greening, more biodiversity and diverse green spaces with healthy soils that reduce heat, emissions and disaster risks.

Rural Development: Enhancing Livelihoods and Sustainability

Solar Water Pumping for Agriculture: In rural areas, access to reliable water sources can significantly impact agricultural productivity. Solar-powered water pumps can provide a cost-effective and sustainable solution for irrigation, enabling farmers to grow more crops and improve their livelihoods.

Community Water Projects: Developing community-managed water projects that use solar energy for purification and distribution can ensure access to clean water in remote areas. These projects can reduce waterborne diseases and improve overall health and wellbeing.

Renewable Energy Cooperatives: Establishing cooperatives where community members collectively invest in and manage solar energy systems can promote local ownership and sustainability. These cooperatives can generate income, reduce energy costs, and empower communities to take charge of their energy needs.

Urban Renewal: Transforming Cities into Green Hubs

Solar Rooftop Programs: Encouraging the installation of solar panels on rooftops of residential, commercial, and public buildings can transform cities into green energy hubs. Incentive programs, such as subsidies and tax credits, can motivate property owners to adopt solar energy.

Integrated Water Management: Urban areas can benefit from integrated water management systems that use solar energy to power water treatment, recycling, and desalination processes. These systems can enhance water security and support sustainable urban growth.

Green Infrastructure: Incorporating green infrastructure elements like green roofs, solar-powered street lighting, and water recycling systems into urban planning can reduce the environmental footprint of cities. These features can also improve air quality, reduce urban heat islands, and enhance the quality of life for residents.

Disaster Resilience: Enhancing Preparedness and Recovery

Portable Solar Solutions: In disaster-prone areas, portable solar power systems can provide critical energy for emergency response and recovery efforts. These systems can power communication devices, medical equipment, and temporary shelters, ensuring that affected communities have the resources they need.

Water Purification in Emergencies: Solar-powered water purification units can be deployed quickly in disaster areas to provide clean drinking water. These units can reduce the risk of waterborne diseases and support the health of affected populations.

Resilient Infrastructure: Building resilient infrastructure that integrates solar and water energy systems can enhance the ability of communities to withstand and recover from natural disasters. This includes designing buildings and facilities that can operate independently of the main grid and ensure continuous access to essential services.

Strategies for Scaling Up: Replication and Adaptation

To maximize the impact of solar and water energy integration, it’s crucial to develop strategies for scaling up successful projects. This involves replicating proven models, adapting them to different contexts, and ensuring that they are sustainable in the long term.

Replication Frameworks: Developing frameworks that outline the key components and best practices of successful projects can facilitate replication in other regions. These frameworks can include technical specifications, implementation guidelines, and lessons learned.

Adaptation to Local Conditions: Adapting projects to local environmental, cultural, and economic conditions is essential for their success. This may involve customizing technology, engaging with local stakeholders, and addressing specific challenges unique to the area.

Sustainability Planning: Ensuring the long-term sustainability of projects requires comprehensive planning, including maintenance, funding, and capacity building. Establishing local management structures and securing ongoing support can help projects remain viable and effective over time.

The integration of solar, water and wind energy offers a transformative pathway towards a sustainable future. By harnessing the power of these renewable resources, we can address critical challenges related to energy access, water scarcity, and environmental degradation. The efforts of Suns Water and similar initiatives are vital in driving this transformation.

As we project developers continue to explore and implement renewable energy solutions, it is critical to foster collaboration, innovation and community engagement. By working together, we can create a world where clean energy and safe water are accessible to all, where environmental sustainability is prioritized, and where artistic expression continues to inspire and mobilize change. Suns Water innovative, creative and advocatory style of working brings many good results, hope and inspiration in the developments. The future is bright, and with the collective effort of individuals, communities, and organizations worldwide, we can achieve a sustainable and resilient planet for generations to come. Together, we can turn the vision of a world powered by solar and water energy into a reality, ensuring a prosperous and harmonious future for all.

Education and Sustainable Development

Empowering young people and future future generations through better education, environmental awareness and commitment to real sustainable goals. One of the most important aspects is promoting a sense of responsibility for the environment and providing the tools and knowledge needed to make a difference - also to ensure that the legacy of sustainable practices continues.

Educational Programs and Curricula

School Partnerships: Partnering with schools to integrate renewable energy and water management topics into their curricula can inspire students from a young age. Interactive lessons, field trips to solar and water energy sites, and hands-on projects can make learning about sustainability engaging and impactful.

University Collaborations: Collaborating with universities to offer courses, research opportunities, and internships focused on renewable energy and water management can prepare students for careers in these fields. Universities can also serve as testing grounds for innovative technologies and approaches.

Online Learning Platforms: Developing online courses and resources that cover various aspects of solar and water energy can reach a global audience. These platforms can provide accessible education for people of all ages, from students to professionals looking to expand their knowledge.

Community Engagement and Awareness Campaigns

Workshops and Seminars: Hosting workshops and seminars on topics related to renewable energy and water management can raise awareness and provide practical knowledge to community members. These events can be tailored to different audiences, from homeowners to local business owners.

Public Awareness Campaigns: Running public awareness campaigns that highlight the benefits and importance of solar and water energy can foster community support. Using various media, such as social media, local newspapers, and community radio, can help reach a wide audience.

Community Events: Organizing community events such as clean energy fairs, art festivals, and sustainability expos can engage the public in a fun and educational way. These events can showcase local projects, provide demonstrations, and offer opportunities for community members to get involved.

Engagement and Leadership

Mentorship Programs: Creating mentorship programs that connect students and young professionals with experienced leaders in the fields of renewable energy and water management can provide valuable guidance and support. These programs can help young people navigate their career paths and develop their skills.

Innovation Challenges and Competitions: Hosting innovation challenges and competitions that encourage young people to develop creative solutions for renewable energy and water issues can stimulate interest and innovation. These events can offer prizes, scholarships, and opportunities for further development of winning ideas.

Technology and Innovation: The Next Frontier

The field of renewable energy is constantly evolving, with new technologies and innovations emerging that have the potential to revolutionize the way we generate and use energy. Staying at the forefront of these developments is crucial for maximizing the impact of solar and water energy integration.

Advanced Solar Technologies

Perovskite Solar Cells: Perovskite solar cells are a promising technology that offers higher efficiency and lower production costs compared to traditional silicon solar cells. Research and development in this area are rapidly advancing, with potential for widespread adoption in the near future.

Bifacial Solar Panels: Bifacial solar panels can capture sunlight from both sides, increasing their efficiency. These panels can be particularly effective in areas with high levels of reflected light, such as snowy or desert regions.

Solar Windows and Building-Integrated Photovoltaics: Solar windows and building-integrated photovoltaics (BIPV) allow for the integration of solar energy generation into the design of buildings. These technologies can turn entire structures into energy producers without compromising aesthetics.

Innovative Water and Wind Technologies

Advanced Water Recycling: Technologies that enhance water recycling processes, such as membrane bioreactors and advanced oxidation processes, can make wastewater treatment more efficient and effective. These systems can be powered by solar energy to further reduce their environmental impact.

Atmospheric Water Generators: Atmospheric water generators (AWGs) extract water from humid air, providing a source of clean drinking water. Solar-powered AWGs can offer a sustainable solution for water-scarce regions.

Solar Thermal Desalination: Solar thermal desalination uses solar heat to evaporate and condense water, separating it from salts and impurities. This method can be more energy-efficient and sustainable compared to traditional desalination processes.

Rethinking traditional wind power generation and further developing Vertical Axis Wind Turbines, which are much more efficient, environmentally friendly and aesthetically pleasing. Some of the best systems are also part of Greening Camps concepts and Energy Storage Parks. Even the flagship projects like the Greenhouse Ship and the Recycling Ship can be powered by VAWTs and produce a lot of hydrogen. The concept papers were published many months ago.

Integrating Artificial Intelligence and IoT

Smart Energy Management Systems: Integrating artificial intelligence (AI) and Internet of Things (IoT) technologies into energy management systems can optimize the use and distribution of solar energy. These systems can predict energy demand, monitor performance, and automate adjustments to improve efficiency.

Water Resource Monitoring: IoT sensors and AI can be used to monitor water resources in real time, providing data on water quality, usage, and availability. This information can be used to manage water resources more effectively and respond to issues promptly.

Predictive Maintenance: AI can predict maintenance needs for solar and water energy systems, reducing downtime and extending the lifespan of equipment. This proactive approach can save costs and improve the reliability of renewable energy systems.

Social Equity and Inclusion

Ensuring Access for All: Efforts must be made to ensure that renewable energy and clean water are accessible to all, regardless of socioeconomic status. This includes implementing policies and programs that support underserved and marginalized communities.

Community-Led Development: Empowering communities to lead their own renewable energy projects can promote social equity and inclusion. Providing resources, training, and support can help communities develop solutions that meet their specific needs and priorities.

Addressing Environmental Justice: Ensuring that the benefits of renewable energy and water projects are equitably distributed is crucial. This involves addressing environmental justice issues.

Long-Term Sustainability and Resilience

Climate Resilience: Developing renewable energy and water systems that can withstand and adapt to the impacts of climate change is essential for long-term sustainability. This includes designing infrastructure that is resilient to extreme weather events and changing environmental conditions.

Sustainable Development Goals (SDGs): Aligning renewable energy and water projects with the United Nations Sustainable Development Goals (SDGs) can provide a comprehensive framework for achieving sustainability. These goals address a wide range of social, economic, and environmental issues.

Global Collaboration: International collaboration and knowledge sharing are critical for addressing global challenges. By working together, countries and organizations can leverage their strengths, share best practices, and develop coordinated strategies for sustainable development.

Super Visions and Visionary Transformation: The Path Forward

As we move forward, let us continue to explore new frontiers, push the boundaries of what is possible, and work together to build a brighter, greener future for generations to come. The vision of a world powered by solar and water energy is within our reach, and with dedication, creativity, and collaboration, we can turn this vision into reality. Together, we can create a sustainable and resilient planet where all life can thrive. Suns Water is the original project or working title for the organization and future company SunsWater™.

The creator of this outstanding project believes in the good forces or powers of humanity, real nature, natural technologies, solar, water and wind energy. That's why he also found many great ideas, developed awesome concepts and projects. The founder and some real scientists believe that most of the water on planet Earth comes or came from the sun. There is a lot of research on how much space water was created in the early days of the formation of the solar system. Most of the water on planet Earth does not come from external sources such as asteroids or meteoroids. Planetary and solar researchers can confirm it. We scientific researchers hope that more people will discuss and exchange about such studies and theories.

The initiator of the Sun's Water Theory has spent many years researching and studying the sun, planets and moons in relation to water and ice. Large data sets and historical archives, internet databases and much more data have been analyzed to determine the actual reality. Mathematical and physical logic can prove that most of the water comes from the sun. Another great discovery made by the founder of the Suns Water project is a solid form of hydrogen, he calls it "Sun Granulate".

The journey towards a sustainable future powered by solar, water and wind energy is both challenging and inspiring. It requires a collective effort from individuals, communities, organizations, and governments worldwide. By embracing innovation, fostering collaboration, and prioritizing education and equity, we can create a world where clean energy and safe water are accessible to all. Through its projects, partnerships, and community initiatives, SunsWater can inspire a global shift towards sustainable practices and technologies.

The concepts and specific ideas are protected by international laws. The information in this article, contents and specific details are protected by national, international and European rights as well as by artists' rights, article, copyright and title protection. The artworks and project content are the intellectual property of the author and founder of the Global Greening Organization and Trillion Trees Initiative. Any constructive and helpful feedback is welcome, as is any active and genuine support.

Global Greening Deserts projects for desalination and hydrogen generation

As the world faces increasing environmental challenges, the integration of solar energy and water energy for sustainable water production and desalination emerges as a promising solution. This innovative approach harnesses the power of the sun and the natural flow of water to address critical issues such as water scarcity and energy consumption. Suns Water, an international artist community project, champions this cause by blending creativity with environmental stewardship. Founded by the visionary leader of the Global Greening Organization, SunsWater embodies a commitment to clean energy, healthy water, and artistic expression.

A Vision for the Future

Suns Water is more than just a project; it is a movement that believes in the universal right to access the sun's energy and water. By creating a global network of artists and environmental advocates, SunsWater™ aims to raise awareness about the potential of natural resources and the importance of sustainable technologies. The project emphasizes the need for environmental consciousness, the exploration of nature's potentials, and the promotion of peaceful technologies that benefit both people and the planet.

Believe in the Powers of the Sun

Solar energy, derived from the sun's radiation, is one of the most abundant and renewable energy sources available. Photovoltaic (PV) panels and solar thermal systems are the primary technologies used to capture and convert solar energy into electricity and heat. The integration of solar energy into water production and desalination processes offers numerous benefits:

Accessibility: Solar technology can be deployed in remote areas, providing access to clean water and energy in regions without reliable infrastructure.

Cost-Effectiveness: Over time, the cost of solar technology has decreased, making it a viable option for large-scale water production and desalination projects. These are just a few short extracts and points from the general concept here.

Sustainability: Solar energy is a clean, renewable resource that reduces reliance on fossil fuels, decreasing greenhouse gas emissions and mitigating climate change.

Combining Solar and Water Energy

The integration of solar and water energy for sustainable water production and desalination holds immense promise for addressing global water scarcity and reducing the environmental impact of water production. Through the efforts of visionary communities like SunsWater community network, many can harness the power of art, technology, and collaboration to create a future where clean energy and healthy water are accessible to all.

SunsWater project developments exemplify the transformative potential of combining environmental awareness with creative expression. By advocating for the sustainable use of natural resources and promoting innovative technologies, Suns Water work inspires a global movement toward a more sustainable and equitable world. As we continue to explore and develop the synergies between solar and water energy, we move closer to a future where the sun's energy and the earth's water resources are used to their fullest potential for the benefit of all life on our planet.

Water energy, or hydropower, is another critical component in the sustainable energy landscape. It involves the generation of electricity through the movement of water, typically in rivers and dams. When combined with solar energy, water energy can enhance the efficiency and reliability of water production and desalination systems. Key advantages include:

Renewability: Like solar energy, hydropower is a renewable resource that can be harnessed without depleting natural reserves.

Efficiency: Hydropower systems can operate continuously, providing a stable and reliable source of energy.

Synergy with Solar: The combination of hydropower and solar energy can create a hybrid system that maximizes energy output and minimizes environmental impact.

Challenges and Opportunities in Solar-Water Energy Integration

Despite the significant potential of combining solar and water energy for sustainable water production and desalination, several challenges must be addressed to realize its full potential. These challenges include technological, economic, and social barriers. However, they also present opportunities for innovation and collaboration.

Technological Challenges

Energy Storage: Solar energy is intermittent, available only during daylight hours, and affected by weather conditions. Effective energy storage solutions, such as batteries or other innovative storage technologies, are essential to ensure a reliable energy supply for desalination processes.

Efficiency: The efficiency of solar-powered desalination systems needs continuous improvement to compete with traditional fossil fuel-based systems. Advancements in photovoltaic technology and desalination methods are crucial.

Scalability: Developing scalable solutions that can be adapted to different regions and scales of operation, from small communities to large urban centers, is a significant technological challenge.

Economic Challenges

Initial Costs: The initial investment required for solar-powered desalination infrastructure can be high. Although costs have decreased over time, financing and funding mechanisms are necessary to support widespread adoption.

Maintenance and Operation: The ongoing costs of maintaining and operating solar and desalination systems must be considered. Ensuring that local communities have the skills and resources needed for maintenance is crucial for long-term sustainability.

Social and Policy Challenges

Awareness and Acceptance: Raising awareness about the benefits of solar-powered desalination and gaining public acceptance are essential for the success of these projects. Educational initiatives and community engagement are key strategies.

Policy Support: Supportive policies and regulations are needed to promote the adoption of solar and water energy technologies. Governments can incentivize the use of renewable energy through subsidies, tax breaks, and favorable regulatory frameworks.

Opportunities for Innovation and Collaboration

Despite these challenges, the integration of solar and water energy presents numerous opportunities for innovation and collaboration. These opportunities can drive the development and adoption of sustainable water production and desalination technologies. GlobalGreening and SunWaters™ research includes:

Research and Development: Continued investment in R&D can lead to breakthroughs in solar and desalination technologies. Partnerships between academic institutions, private companies, and government agencies can accelerate innovation.

Public-Private Partnerships: Collaboration between the public and private sectors can facilitate the development of large-scale solar-powered desalination projects. Such partnerships can leverage the strengths and resources of both sectors.

Community-Based Initiatives: Engaging local communities in the development and operation of solar-powered desalination systems ensures that projects meet local needs and gain community support. Training and capacity-building programs can empower communities to take ownership of these initiatives.

Global Collaboration: International cooperation and knowledge-sharing can help disseminate best practices and successful models of solar-powered desalination. Organizations like the Global Greening Institution and Suns Water can play a pivotal role in fostering global collaboration and raising awareness about the potential of these technologies.

Solar-Powered Desalination: A Sustainable Solution for Water Scarcity

Desalination, the process of removing salt and impurities from seawater, is a critical technology for addressing global water scarcity. Traditional desalination methods, such as reverse osmosis and distillation, are energy-intensive and often rely on fossil fuels. However, solar-powered desalination offers a sustainable alternative. Here are some short summaries.

Environmental Benefits: By using solar energy to power desalination plants, we can reduce the carbon footprint associated with water production.

Energy Efficiency: Solar desalination systems can be designed to optimize energy use, making them more efficient than traditional methods. This is just one special field SunsWaters professional academics, connected experts and project developers have long-term experiences.

Scalability: Solar-powered desalination can be scaled to meet the needs of different communities, from small villages to large cities. Funding early stage developments, innovative startups and research research can accelerate innovation in solar and water energy technologies.

Suns Water: A Catalyst for Change

SunsWater™ is uniquely positioned to be a catalyst for change in the realm of sustainable water production and desalination. By leveraging its network of artists and environmental advocates, Suns Water can inspire and mobilize people around the world to support and adopt clean energy technologies.

Art as Advocacy: Art has the power to communicate complex ideas and inspire action. Through exhibitions, installations, and multimedia projects, Suns Water can raise awareness about the potential of solar and water energy and the importance of sustainable water management.

Educational Programs: Suns Water can develop educational programs and workshops that teach communities about the benefits and practicalities of solar-powered desalination. These programs can empower individuals to become advocates for clean energy in their own regions.

Collaborative Projects: By partnering with other organizations, governments, and the private sector, Suns Water can initiate and support collaborative projects that demonstrate the feasibility and benefits of solar-powered desalination.

The Impact of Solar and Water Energy on Communities

The implementation of solar and water energy systems can have profound impacts on local communities, particularly in regions facing water scarcity and energy poverty. During the years Greening Deserts founder developed many awesome concepts and project developments in this direction.

Economic Benefits

Job Creation: Developing and maintaining solar and hydropower infrastructure creates jobs in engineering, construction, and operations, boosting local economies. Read more in the Greening Camp concept papers.

Cost Savings: Communities can save money on energy and water bills through the use of renewable energy, which often has lower operational costs than conventional energy sources.

Environmental and Health Benefits

Reduction in Pollution: Solar and hydropower systems produce no air pollution or greenhouse gases, contributing to cleaner air and a healthier environment.

Access to Clean Water: By providing a reliable source of energy for water purification and desalination, these systems can ensure access to safe drinking water, reducing the incidence of waterborne diseases.

Social Benefits

Community Empowerment: Access to reliable and sustainable energy and water sources empowers communities to develop local industries, improve education, and enhance overall quality of life.

Climate Resilience: Renewable energy systems can enhance the resilience of communities to climate change by providing stable energy and water supplies even in adverse conditions.

The Role of Suns Water in Promoting Sustainable Technologies

Renewable energy sources, particularly solar and hydropower, play a critical role in sustainable water management. They provide the necessary energy to produce and purify water without the environmental drawbacks associated with fossil fuels. By integrating these energy sources into water management systems, we can create more resilient and sustainable infrastructure.

Suns Water plays a crucial role in advocating for the integration of solar and water energy through its community of artists and environmentalists. By creating and sharing art that highlights the beauty and potential of natural resources, Suns Water inspires others to join the movement for a greener, more sustainable future. The project also serves as a platform for sharing knowledge and best practices, encouraging collaboration and innovation in the field of clean energy and water production.

The integration of solar and water energy for sustainable water production and desalination represents a transformative approach to addressing some of the world's most pressing challenges. Through the efforts of communities like Suns Water, we can harness the power of the sun and water to create a healthier, more sustainable planet. By combining art, technology, and environmental awareness, we can inspire a global movement toward clean energy and healthy water for all.

Future Directions and Innovations

The future of solar and water energy integration is bright, with ongoing research and technological advancements promising to enhance efficiency, reduce costs, and expand applications. Key areas of future development include:

Advanced Materials: Innovations in materials science, such as more efficient photovoltaic cells and durable membranes for desalination, can significantly improve the performance of solar and water energy systems.

Artificial Intelligence and IoT: Integrating AI and IoT technologies can optimize the operation and maintenance of renewable energy systems, ensuring they run efficiently and respond dynamically to changing conditions.

Decentralized Systems: Developing decentralized, off-grid renewable energy and water production systems can provide reliable services to remote and underserved areas, enhancing equity and access.

Policy and Regulatory Support: Continued advocacy for supportive policies and regulations is essential to foster the adoption and scaling of solar and water energy technologies. This includes incentives for renewable energy projects, investments in research and development, and frameworks for international collaboration.

The integration of solar and water energy for sustainable water production and desalination represents a pivotal opportunity to address some of the most pressing challenges of our time. Through the combined efforts of communities like SunsWater, governments, researchers, and industry leaders, we can harness the full potential of these renewable resources to create a more sustainable and equitable world.

Suns Water is a global project development and community for arts, clean energy and green technology. We believe that suns energy and water is free for all life on planet Earth. SunsWater is a brand and fantasy name created by the founder of the Global Greening Organization. We artists believe that more people should focus on environmental awareness, nature potentials, natural and peaceful technologies, peacebuilding and healty waters.

SunsWater™, with its unique blend of artistic expression and environmental advocacy, plays a crucial role in this transformative journey. By fostering a global network of artists and environmentalists, Suns Water inspires creativity, collaboration, and innovation in the pursuit of clean energy and healthy water. As we look to the future, the vision and efforts of such communities will be instrumental in shaping a world where the sun's energy and the earth's water resources are harnessed sustainably for the benefit of all life on our planet.

The information in this article, contents and specific details are protected by national, international and European rights as well as by artists' rights, article, copyright and title protection. The artworks and project content are the intellectual property of the author and founder of the GlobalGreening Organization and Trillion Trees Initiative.

The more you all support all these good developments the faster you will help to establish the project goals and connected projects like Desert Hemp and the Peace Letters project. If you help us you will help yourself at the end. Never forget in nature on planet Earth nearly everything is connected. Any constructive and helpful feedback is welcome, as is any active and financial support.

Top 5 Eco-Friendly Technologies You Need to Know About

Introduction

Eco-friendly technologies are designed not to disturb nature and its processes. The domains of such technologies include energy, transportation, construction, waste management, and many more. This blog outlines 5 of the best eco-friendly technologies that create a visible difference as we walk towards becoming a sustainable world. Read to continue link

Solar panel for Irrigation ( Nimbus solar Solution)

Farmers need continuous water supply for irrigation so that they can maximize production. Nimbus solar solutions have helped farmers across the country to increase the yield and help them ear extra revenue. These systems reduce water usage and dependence on other sources for supply

Scientists have developed a new solar-powered system to convert saltwater into fresh drinking water which they say could help reduce dangerous the risk of waterborne diseases like cholera.

Via tests in rural communities, they showed that the process is more than 20% cheaper than traditional methods and can be deployed in rural locations around the globe.

Building on existing processes that convert saline groundwater to freshwater, the researchers from King’s College London, in collaboration with MIT and the Helmholtz Institute for Renewable Energy Systems, created a new system that produced consistent levels of water using solar power, and reported it in a paper published recently in Nature Water.

It works through a process called electrodialysis which separates the salt using a set of specialized membranes that channel salt ions into a stream of brine, leaving the water fresh and drinkable. By flexibly adjusting the voltage and the rate at which salt water flowed through the system, the researchers developed a system that adjusts to variable sunshine while not compromising on the amount of fresh drinking water produced.

Using data first gathered in the village of Chelleru near Hyderabad in India, and then recreating these conditions of the village in New Mexico, the team successfully converted up to 10 cubic meters, or several bathtubs worth of fresh drinking water. This was enough for 3,000 people a day with the process continuing to run regardless of variable solar power caused by cloud coverage and rain.

[Note: Not sure what metric they're using to calculate daily water needs here. Presumably this is drinking water only.]

Dr. Wei He from the Department of Engineering at King’s College London believes the new technology could bring massive benefits to rural communities, not only increasing the supply of drinking water but also bringing health benefits.

“By offering a cheap, eco-friendly alternative that can be operated off the grid, our technology enables communities to tap into alternative water sources (such as deep aquifers or saline water) to address water scarcity and contamination in traditional water supplies,” said He.

“This technology can expand water sources available to communities beyond traditional ones and by providing water from uncontaminated saline sources, may help combat water scarcity or unexpected emergencies when conventional water supplies are disrupted, for example like the recent cholera outbreaks in Zambia.”

In the global rural population, 1.6 billion people face water scarcity, many of whom are reliant on stressed reserves of groundwater lying beneath the Earth’s surface.

However, worldwide 56% of groundwater is saline and unsuitable for consumption. This issue is particularly prevalent in India, where 60% of the land harbors undrinkable saline water. Consequently, there is a pressing need for efficient desalination methods to create fresh drinking water cheaply, and at scale.

Traditional desalination technology has relied either on costly batteries in off-grid systems or a grid system to supply the energy necessary to remove salt from the water. In developing countries’ rural areas, however, grid infrastructure can be unreliable and is largely reliant on fossil fuels...

“By removing the need for a grid system entirely and cutting reliance on battery tech by 92%, our system can provide reliable access to safe drinking water, entirely emission-free, onsite, and at a discount of roughly 22% to the people who need it compared to traditional methods,” He said.

The system also has the potential to be used outside of developing areas, particularly in agriculture where climate change is leading to unstable reserves of fresh water for irrigation.

The team plans to scale up the availability of the technology across India through collaboration with local partners. Beyond this, a team from MIT also plans to create a start-up to commercialize and fund the technology.

“While the US and UK have more stable, diversified grids than most countries, they still rely on fossil fuels. By removing fossil fuels from the equation for energy-hungry sectors like agriculture, we can help accelerate the transition to Net Zero,” He said.

-via Good News Network, April 2, 2024

There were two kinds of landscape characteristic of the inner planets of the Sun: the purposeful and the desolate. Purpose informed every scene on Earth, the planet that produced life, because every detail there had its "benefit," its teleology. True, it did not always— but billions of years of organic labor had accomplished much: thus flowers possessed color for the purpose of attracting insects, and clouds existed for the purpose of dropping rain on pastures and forests. Every form and thing was explained by some benefit, whereas what was clearly devoid of any benefit, like the icebergs of Antarctica or the mountain chains, constituted an enclave of desolation, an exception to the rule, a wild though possibly attractive waste. But even this was not certain, because man— undertaking the deflection of the course of rivers to irrigate areas of drought, or warming the polar regions— paid for the improvement of some territories with the abandonment of others, thereby upsetting the climatic equilibrium of the biosphere, which had been adjusted so painstakingly (though with seeming indifference) by the efforts of natural evolution. It was not that the ocean depths served the creatures there with darkness, to protect them from attack— a darkness they could light, as they needed, with luminescence— but vice versa: the darkness gave rise precisely to those that were pressure-resistant and could illuminate themselves.

On planets overgrown with life it was only in the depths, in caves and grottoes, that the creative power of nature could timidly express itself, a power that, not harnessed to any adaptational requirement, or hemmed in, in the struggle for survival, by the competition of its own results, could create— over billions of years, with infinite patience, in droplets of hardening salt solutions— phantasmagoric forests of stalactites and stalagmites. But on such globes this was a deviation from the planetary labors, a deviation locked away in vaults of rock and therefore unable to reveal its vigor. Hence the impression that such places were not usual in nature but, rather, spawning grounds for monstrosities only on the fringe of things. Infrequent exceptions to the statistical rule of chaos.

In turn, on globes parched like Mars or, like Mercury, immersed in a violent solar wind, the surfaces, due to that rarefied but incessant exhalation from the mother star, were lifeless wastes, since all raised forms were eroded by the fiery heat and reduced to dust that filled the crater basins. It was only in places where eternal, still death reigned, where neither the sieves nor the mills of natural selection were at work, shaping every creature to fit the rigors of survival, that an amazing realm opened up— of compositions of matter that did not imitate anything, that were not controlled by anything, and that went beyond the framework of the human imagination.

imagination. For this reason, the fantastic landscapes of Titan were a shock to the first explorers. People equated order with life, and chaos with a dreary inanimateness. One had to stand on the outer planets— on Titan, the greatest of their moons— to appreciate the full error of this dichotomy-dogma. The strange formations of Titan, whether relatively safe or treacherous, were ordinary rubble heaps of chaos when viewed from a distance and a height. But they did not appear so when one set foot on the soil of this moon. The intense cold of this whole sector of space, in which the Sun shone but gave no heat, proved to be not a throttle but a spur to the creativity of matter. The cold, indeed, slowed the creativity, but in that very slowing gave it an opportunity to display its talent, providing a dimension that was indispensable to a nature untouched by life and unwarmed by sun: time— time on a scale where one million centuries, or two million, was of no significance.

The raw materials here were the same chemical elements as on Earth. But on Earth they had entered the servitude, so to speak, of biological evolution and only in that context amazed man with subtlety— the subtlety of the complex bondings that combined to form organisms and the interdependent hierarchies of species. It was therefore thought that high complexity was a property not of all matter but only of living matter, and that chaos in the inorganic state produced nothing more than haphazard volcanic spasms, lava flows, rains of sulfurous ash.

The Roembden Crater had cracked, once, at the northeast on its large circle. Then a glacier of frozen gas crept through the gap. In the following millennia, the glacier retreated, leaving on that furrowed terrain mineral deposits— the delight and vexation of the crystallographers and other, no less dumbfounded scientists. It was indeed a sight to see. The pilot (now operator of a strider) faced a sloping plain ringed by distant mountains and strewn with … with what, exactly? It was as if the gates of unearthly museums had been flung open and the remains of decrepit monsters had been dumped in a cascade of bones. Or were these the aborted, insane blueprints for monsters, each one more fantastic than the last? The shattered fragments of creatures that only some accident had kept from participating in the cycles of life? He saw enormous ribs, or they could have been the skeletons of spiders whose tibiae eagerly gripped blood-speckled, bulbous eggs; mandibles that clung to each other with crystal fangs; the platelike vertebrae of spinal columns, as if spilled out in coin rolls from the bodies of prehistoric reptiles after their decay.

This eerie scene was best viewed, in all its wealth, from the height of the Digla. The area near Roembden was called, by the people there, the Cemetery— and in fact the landscape seemed a battlefield of ancient struggles, a burial ground that was an exuberant tangle of rotting skeletons. Parvis saw the smooth surfaces of joints that could have emerged from the carcass of some mountainous monstrosity. One could even make out on them the reddish, bloodclotted places where the tendons had been attached. Nearby were draped skin coverings, with bits of hair that the wind gently combed and lay in changing waves. Through the mist loomed more many-storied arthropods, gnawing through one another even in death. From faceted, mirrorlike blocks thrusted antlers, also gleaming, among a spill of femurs and skulls of a dirty-white color. He saw this, realizing that the images that arose in his brain, the macabre associations, were only an illusion, a trick of the eyes shocked by the strangeness. If he dug methodically in his memory, he would probably remember which compounds yielded— in a billion-year chemistry— precisely these forms that, stained with hematites, impersonated bloody bones, or that went beyond the modest accomplishments of terrestrial asbestos to create an iridescent fluff as of the most delicate fleece. But such sober analysis would have no effect on what the eyes saw.

For the very reason that here nothing served a purpose— not ever, not to anyone— and that here no

guillotine of evolution was in play, amputating from every genotype whatever did not contribute to survival, nature, constrained neither by the life she bore nor by the death she inflicted, could achieve liberation, displaying a prodigality characteristic of herself, a limitless wastefulness, a brute magnificence that was useless, an eternal power of creation without a goal, without a need, without a meaning. This truth, gradually penetrating the observer, was more unsettling than the impression that he was witness to a cosmic mimicry of death, or that these were in fact the mortal remains of unknown beings that lay beneath the stormy horizon. So one had to turn upside down one's natural way of thinking, which was capable of going only in one direction: these shapes were similar to bones, ribs, skulls, and fangs not because they had once served life— they never had— but only because the skeletons of terrestrial vertebrates, and their fur, and the chitinous armor of the insects, and the shells of the mollusks all possessed the same architectonics, the same symmetry and grace, since Nature could produce this just as well where neither life nor life's purposefulness had ever existed, or ever would.

-Lem, Fiasco

i really love this excerpt in concept, i think ive posted it before, but empirically it seems false, which is weird. if we consider a very large system we see elaborate structure, long distant current-cycles in the ocean, or the great red spot, or all sorts of sun stuff. but at the human scale, on other planets, we dont see much structure at all. we just see rocks, in plain convex shapes.

Yukon Mountains, November 2024

"Fire worm" was the rough translation of what the locals were calling the thing slowly undulating in a spiral around her fire watch tower perch. The titanic creature was no less than thirty feet long, unwound from the ball it was in, and covered in minute translucent hairs that gave it a glassy appearance. Its thousand legs were tipped with spines and vestigial lizard-like arms wrapping around each joint. Steam hissed out of its body with the smallest movements.

Her worm had been scoping the huge expanse, and creating caves in the building-depth snowfall and irrigating the frozen earth. It used to be a millipede, now it's a "fire worm". Looking at it over the wood guard rail, it looked like a glass, many legged whirlpool.

It's been eating wasting deer out here, exercising one of the benefits of Chrysalid's demand on the proteins around it.

"Well? Go."

It doesn't want to go, but the beast unfurls, one long, pointed leg at a time. It sludes against large banks of snow and mud until it vanishes under a patch of soft earth as a myth in the mountain range.

Carla's watch tower had become a space she had committed for herself. A perfect rectangle, she'd installed bio batteries and solar panels to power a collection of things she'd began to accrue.

It's only been two years. It's not as occupied as it could be. It's a self testing lab, and a pharmacological closet. Managing her own infection had always and only ever been her responsibility, and that hadn't changed. She didn't want it to.

And when the creature leaves, she turns to head back to the literal drawing board inside of it, the outside world closed off with tinted windows.

@separatedway

Food, energy and water insecurity are ongoing concerns in East Africa, agrivoltaic systems address all three

This paper shows data for agrivoltaic systems in Tanzania and Kenya that generate power, produce food and conserve water, demonstrating their viability for both grid-tied agribusinesses and rural, off-grid projects. 

The research indicates that certain crops such as maize, Swiss chard and beans thrived in the partial shade offered by solar panels.

“The positive yield results for Swiss chard have promising implications for growing nutritious crops with agrivoltaics. The control plot was sufficiently irrigated, with yields comparable to those in a rainfed study in South Africa, so drought stress does not explain the lower yields compared to the agrivoltaic plot.

“Instead, the partial panel cover is potentially creating a more suitable growing environment by protecting the crops from heat stress and/or UV damage,” the report said. 

It notes that some crops produced more food using less water, ��valuable in a region where water scarcity threatens food security, most farmers rely on rainfall for their crops, and climate change is likely to make rainfall less predictable.”

Innovative business models for small scale solar powered irrigation

If rolled out at scale, solar-powered irrigation systems hold huge potential. They work for smallholder farmers, who account for 80% of sub-Saharan Africa’s farms, according to the UN Food and Agriculture Organization. But they also displace expensive and polluting diesel pumps and can, if managed correctly, contribute to efforts to manage scarce water resources well for the long term.

Chiefly, there is the issue of affordability. Farmers need to be able to pay the upfront cost of a solar-powered irrigation system and to pay for the duration of its use. When compared with the diesel-fueled irrigation pumps many farmers use today, the total lifetime cost of solar powered irrigation systems can be substantially lower. We estimate farmers can save 40% to 60% on irrigation costs.

As we see across the off-grid solar sector, adopting a pay-as-you-go (PAYG) approach – or, in our case, pay-as-you-grow – has the benefit of allowing farmers to pay for their systems over time, as their income increases due to better harvests.

Moving on from affordability, maintenance is the next key challenge, particularly in remote and rural areas where farms can be hard to reach and the availability of trained technicians is limited. By managing the lifecycle of pumps from design through manufacture, finance, installation, and maintenance, companies can work with farmers to ensure that pumps are able to continue to function in often challenging local conditions, season after season.

Internet-of-things (IoT)-enabled technology enables trained teams to monitor pump performance and conduct maintenance remotely. This is complemented by strategically located sales and service centers and a distributed team of field engineers able to rapidly respond to maintenance issues, expand local capacity and minimize downtime for farmers reliant on irrigation for successful harvests.

Again, solar-powered irrigation has an advantage over diesel pumps in that their fuel source is abundant and locally available. Fewer moving parts also make solar-powered irrigation systems less liable to break down than their diesel counterparts.

Source

The Seeds We Sow

The fic + art collaboration Art completed by @mirandemia for the @ahsokaevents Wildflowers collab! Find it on AO3!

Sabine Wren + Ahsoka Tano The soil was warm under her hands; Freshly turned and clumpy where she uncovered it from the ashen tones of the earth. “Life finds a way.” Ahsoka had told her upon setting out on this task. The water source wasn’t too far away, a still pool with sediment floating in the murky water. 

“We can get this cleaned up, can’t we Asha?” She called to the howler, snuffling through a patch of stubbornly prevailing grass nearby. She did not receive any response from the peculiar creature, though it was nice to have her to bounce ideas off of. 

The Noti had given her the scraps from an older trawler, dragged each time they moved to limit waste, carrying broken vaporators, gears, and even old power packs to blasters that must have been acquired from Thrawn’s troopers. At least she didn’t need to lug it too much further than their current campsite to get it near the water supply.  “Let’s see what we can do,” The Mandalorian talked aloud, boots crunching over the crumbling outer layer of the planet’s crust. 

First, Sabine grabbed old pipes from blown cooling systems, using her hands to dig out four long rows in the dirt, exposing nutrient-rich soil to the sunlight above. “Bet you guys missed the sun just as much as I do,” She chuckled warmly to a squirming lifeform. “You kinda look like an exogorth. Can I call you Exo?” The pad of her thumb brushed along the sliminess of the creature's side, laughing warmly to herself when it squiggled away. “Alright, Exo. I’m sorry I gotta move you, but hey, you keep pests away from my seeds, and this can be a mutually beneficial arrangement, got it?” 

The creature was set inside of a pile of upturned dirt, where it happily burrowed itself to be rid of the humanoid that dared interrupt its rest. 

Building the irrigation system was nothing new to Sabine Wren; In fact, it was something she understood almost as well as mixing her explosive paints. Back when rebel holdouts needed crops, she was often the one counted on to help them get started, and it was always something that helped her feel useful. 

A Mandalorian could destroy, and conquer, and a million other destructive things, but she was put in this Galaxy for more than that. She created, and saved, she strived every day for as long as she could remember to embrace her Mandalorian heritage, to be everything her ancestors could have wanted, and then some. 

It was through her continued work every day that she honored the patron of her House, Tarre Vizsla, it was through her dedication to her people that honored her Clan and the lives they’d once lived, and it was her determination that honored the Rebellion she’d spent so long fighting for. Everything she did was for her family, and right now? That family was found in Ahsoka and the Noti. 

Her purification system was simple in design, and it required the sacrifice of a power pack from her blaster to generate enough of a spark to keep the miniature solar array working. She could return with a new source for it one day, for when the sun grew dim and the gears needed to turn. For now, the blaster she’d painted in the blues of reliability and royalty was dismantled under a caring hand and slotted into the home of the system. 

Clean water trickled slowly with a quiet whir of machinery, sucking the water through and filtering out sediment as it pushed along the rows of water she’d dug out. “Hey, we did it,” She called to Asha, now dozing lazily in her interesting patch of grass. “Thanks,” She laughed, bubbling like the carbonation in The Outlander Club’s specialty beverage, warmed by the lull of a punk tongue hanging lazily past yellowed canines. 

With dampened soil, Sabine was able to meticulously lay each seed; They were from her Galaxy, so there was no telling if they would take to their new home, but she had hope, and she’d learned long ago just how far a little hope could stretch. Then, the compost that had been saved up was spread evenly over the rows, pressed in lightly to allow for the sprouts to push past without much resistance, though would not risk being washed away when the drought on this side of the planet would end at last. 

“You’ve done well,” Ahsoka’s voice was warm; Lighter than she was used to, over the course of her previous apprenticeship, that is. 

“Yeah? You think so?” The Mandalorian questioned genuinely from her spot knelt in the dirt, mud caked her armor and her flight suit, and streaks painted her face and dirtied her hair. The purple-haired woman turned her head to watch as Ahsoka dismounted her howler, allowing it to trundle to Asha’s lazy form. “I do,” The hand on her shoulder was warm. Sabine allowed the offered strength to rise from her knelt position. “Lunch is ready back at camp, you look like you could use it,” The jab was light, bouncing off her armor with a light chuckle. 

“You’re tellin’ me… Think everything will be safe here?” 

Ahsoka’s gaze turned to the horizon, searching. When she shook her head in the affirmative, Sabine’s shoulders relaxed. “Do you think they’re okay…” She questioned after a moment. 

It didn’t take a genius to understand who she was asking after. “Shin will be alright, I’m sure of it. Baylan… worries me, he’s treading a dangerous path, one we will have to follow, sooner than later.” 

As the Master and Apprentice rode their howlers the short distance back to camp, Sabine’s fingers threaded through the thick, dark wool of Asha’s neck. “Thanks,” 

Ahsoka’s head bowed towards her. She could have kept the thoughts to herself, as she’d once had. But even Ahsoka Tano learned when it was time to truly be more than the people who’d trained you. Where Obi-Wan and Anakin may have kept themselves quiet, she was determined to break the cycle.  Shin Hati

Communication with the bandits was slow. Truly, Shin had heard of droids learning and adapting better than this sorry lot. All she received from them were grunts, either of indignation, or approval, she could only tell after they’d begun moving, either to follow her orders or to blatantly ignore them. 

The most recent act of ignorance from the clan found Shin stubbornly figuring out ways to feed them all. They’d seemed unbothered by the prospect that they could go hungry, as if they could pillage their way across Peridea; and maybe they could have, if not for the Jedi and Sabine protecting their favorite victims now. Shin knew better than to allow themselves to march into that camp, she knew what the Torguta and Mandalorian were capable of. 

Chasing away the nomads that had settled in this desolate canyon had been simple, natural, even. The moment they saw a blood-orange blade on the horizon, and saw the sun glinting off the worn paint of her bandit’s heads, most were intelligent enough to turn tail. It had even stocked them up with enough supplies to last until… well… Until what, Shin wasn’t sure yet, but they’d be damned if they didn’t figure it out soon. 

There was a water source nearby, old, rickety purifiers ran as they refilled the jugs as fast as her men could deplete them. They also noticed a raised bed of soil, something she didn’t see often in the wastes like this. There were no seeds nearby, though she could see plants sprouting from a host nearby. 

Eyes as dreary as their landscape peered around the supplies that had been left. This was new, but they had always been a resourceful student. If taking lives was so natural, then surely they would be able to sustain it, especially in the most non-sentient way life existed.

The soil had been freshly turned, Shin learned as their fingers delved into the raised garden bed. The travelers had been planning on making this place their home for the season as well. No matter, it was Shin’s people who were victorious in the end, and they would reap the profits of prior labors… and Shin’s own. 

Dirt spilled into the many tears in their gloves, worn from the months of use and with no true materials to repair them. The pebbles were harsh, though their skin was learning to grow harsher. Eventually, the tanned gorraslug material was set aside, resting precariously on a wooden support, allowing them to dig deeper, pushing grime up under their fingernails as they worked to bury the remains of the food supply. 

Plasto pails sat near the purifiers, and it was just Shin’s luck that the first pail they filled with water would crack under the unforgiving weight as it was filled to the brim. “Karabast!” They growled at the remains of the bucket, water soaking their boots and turning the ground at their feet into sloshing mud. 

The Force, a fickle ally, refused to answer their call in their growing frustrations; Even as they attempted to channel their annoyance into the pressure of water, thin plasto, and the space they wanted to create between it and the ground. 

Huffing and puffing, Shin found themselves resorting to other means; A spear was sent between the weak metal handles of the pail, allowing her the leverage to lift it, keeping it balanced on her shoulder with minimal spillage as she lugged it to the beds, cursing the whole way. 

By the time each sprout had a home in the dirt, Shin’s hands, tunic, and face were streaked with mud, sweat cutting tracks through the grime as they sat back against a boulder to admire their work. A bandit passed by them, Shin watched with narrowed eyes as they paused at her work. 

No words were spoken between them as they turned back to look at the filthy blonde, though Shin had felt the understanding in the nod of their head. A dented canteen was removed from their hip and passed nonchalantly to her on their way back to sorting through their treasures of the raid. 

The sinking of the sun was met with a wet nose sniffling at long-dry boots, a dirty white howler in search of food. With her fingers carding through the soft fur at its neck, Shin rose at last, acquiescent to find the poor beast something to eat, and with a rumbling of her own stomach, something for herself as well. 

Ezra Bridger Krownest had always been cold, but if there was anything Ezra Bridger had learned in his short experiences with Clan Wren, it was the planet's unique ability to nurture all kinds of life. 

This was why, as the Ghost touched down on a desolate surface, and no gruff voices came over their comms to demand clearance, Ezra felt the loss of those unique lives as distinctly as he had. The Jedi paused in the entryway, boot hovering just over the ramp. “Ezra?” Hera called, a gloved hand coming to rest on his shoulder. 

A deep breath and a warm smile recentered him as he used the familiar touch on his shoulder to ground himself. “I’m alright… It’s just hard not to notice…” 

Hera’s head dipped in understanding; She hadn’t made the venture yet, had been waiting on Sabine’s word to visit with the heir, the day had never come, until Ezra voiced his desire to do something for her family. “We’ll be right here with you,” She promised, glancing away from Ezra to peek down at Jacen, bundled up and standing by her side, with Chopper rolling just behind them once they began walking. 

The Wren stronghold was dark and untouched, mountains of snow coated the roof, while dangerous icicles hung dangerously along the large transparisteel windows. “Do you think it’ll grow here?” Jacen asked as the toe of his boot caught on a  patch of slippery ice. . 

“Yeah, ‘course,” Ezra mused out loud as he knelt near one of the windows. Peering through the dust, he could see the inside of the throne room, dark and desolate, with cobwebs hanging across each surface. The light that managed to cut through the grime still found a way to cast across the painting of the Matriarch of Clan Wren, lighting yellow and grey armor up in an effect that made them glow gold and silver. 

“Do you remember how it went?” Ezra questioned, unblinking from his sight against the glass, catching the barest reflection of his own eyes back at him. 

“Never did manage Mando’a,” Hera admitted, lowering herself into the snow beside him, allowing Jacen to tuck himself against her once more as she settled. He’d known Ursa, though Hera doubted he would have much memories of them, not with the separate wars they found themselves fighting as Sabine focused on finding Ezra. 

“Basic should be fine… It’s the memory that counts, right?” He tried to keep his tone light, tried to keep the calmness steady, though the emptiness seemed to echo the way his words caught around the tightness in his throat. Addam’s apple bobbing, he nodded his head towards the snow, beginning the process of clearing away the piles to the frozen earth underneath. 

They did not have every name of every warrior lost, and Ezra found himself regretting this, too naive and headstrong, too worried about the fight than the lives of the people he’d fought beside. He would return, when the seasons changed, when Sabine came out. She could tell them their names, and they would plant flowers for them as well, as a family again. 

The ground was frozen and solid, though after a while of digging and chipping away, he’d been successful in clearing three small holes. “Vormur can grow through anything,” He assured himself as he retrieved a small duracrete container, filled to the brim with dirt from Lothal, soft enough to cover the tops and hopefully prevent them from freezing over. “They’re Mandalorian, you know” A foreboding gaze was sent to the portain through the windows before he dropped a seed in each hole. Hera stayed silent, for him, for Sabine and Ahsoka, and for Clan Wren itself. 

“Jace, you wanna cover this up, for aunt ‘bine?” He offered, leaning back as he cleared his throat, hiding a sniffle as he wiped the rough nylon material of his sleeve under his nose. Small knees shuffled through the dirt as the boy inched closer, mittens sweeping through the uncovered dirt to start brushing it to the small array of flowers. “These smell really nice,” He commented as he worked, taking a big sniff as the dirt began to settle. “Aunt Sabine will really like this when she comes back-” The young Force-Sensitive boy paused then, fingers curling in his mittens as his brows drew together. “If she ever comes back…. Here, i mean.” He was quick to correct; No one aired their thoughts about the possibility of Sabine and Ahsoka’s return, not when Ezra himself had been gone so long. 

“Well, when she hears about all our hard work… I’m sure she will,” Hera’s hand brushed over Jacen’s head, pulling the wool hat on his head askew. Final preparations were made to keep the flowers healthy and strong from the climate. Just as the sun began to crest the mountains, pink and golden light splashing across the grey landscape of the frozen lake. Before they could leave, the Rebels settled back in one last time, peering through dust covered windows at the haunting silhouette of the Countess of Krownest one last time. “Ni su'cuyi, gar kyr'adyc, ni partayli, gar darasuum, Clan Wren.” Their Mando’a was rough and heavily accented, but the words seemed to release some of the weight on their shoulders, allowing them to return to their new war with a lighter conscience.