Grew Energy Joins Hands With IIT Bombay To Enhance R & D Initiatives In Photovoltaic Technology

GREW Energy Private Limited, the youngest and fastest-growing player in India's renewable energy landscape, has announced a strategic partnership with the esteemed Indian Institute of Technology, Bombay (IIT Bombay). This collaboration represents a significant milestone in the company's efforts to advance photovoltaic technology and contribute to the ambitious goals of renewable energy in India.

This alliance brings together the cutting-edge research expertise of IIT Bombay and Grew Energy's deep industry knowledge to enhance solar cell manufacturing and module development. The IIT Bombay partnership will focus on several key areas, including performance characterization, reliability assessments, and the creation of next-generation PV technologies. Additionally, it will foster joint consultancy projects, create internship opportunities, facilitate intellectual property licensing, and provide workforce training initiatives that will shape the future of solar energy innovation in India.

A delegation from IIT Bombay, led by prominent researchers, recently visited Grew Energy's manufacturing facility in Dudu, Jaipur. This visit laid the foundation for collaborative efforts that aim to bridge the gap between research and industrial application, ensuring that innovations in photovoltaic technology are effectively implemented in real-world scenarios.

Vinay Thadani, Director and CEO of Grew Energy, expressed his enthusiasm for the collaboration: “This partnership with IIT Bombay underscores our unwavering commitment to driving innovation and leading the solar energy sector. By combining our industry experience with IIT Bombay’s research capabilities, we are poised to make significant breakthroughs in solar energy innovation that will not only benefit India but also contribute to the global renewable energy landscape.”

Prof. Upendra Bhandarkar, Associate Dean of R&D at IIT Bombay, highlighted the importance of this partnership: “Working with Grew Energy allows us to translate our research into practical applications, advancing India’s renewable energy goals. This collaboration reflects our shared vision of leveraging technology to create sustainable energy solutions for the future.”

Prof. Anil Kottantharayil, Professor In-Charge of the Photovoltaic Technology and Innovation Centre (PoTIC) at IIT Bombay, echoed this sentiment: “Our engagement with Grew Energy is a testament to our commitment to enhancing the technological competitiveness of the photovoltaic technology sector in the country. This partnership will enable us to push the boundaries of PV technology and contribute to the growth of the renewable energy industry in India.”

This IIT Bombay partnership is set to play a pivotal role in shaping the future of solar energy innovation in India. By integrating advanced research with practical industry applications, Grew Energy and IIT Bombay are not only enhancing the efficiency and reliability of photovoltaic technology but also contributing to the larger goal of achieving a sustainable and energy-independent future for India.

For more: Grew Energy Joins Hands With IIT Bombay To Enhance R & D Initiatives In Photovoltaic Technology

Thin-film Amorphous Silicon Solar Cell Market Research, Analysis, Demand, Overview and Regional Outlook Study 2017 – 2032

The market for solar photovoltaic (PV) cells based on thin layers of amorphous silicon, a non-crystalline type of silicon, is known as the thin-film amorphous silicon solar cell market. In comparison to conventional crystalline silicon sun cells, these thin-film solar cells provide benefits including flexibility, light weight, and low production costs. The demand for thin-film amorphous silicon solar cells is described in the following way:

Market Overview: In recent years, the thin-film amorphous silicon solar cell market has seen rapid expansion. The market has grown as a result of the rising demand for renewable energy, improvements in thin-film solar cell technology, and the requirement for affordable solar solutions. Applications for thin-film amorphous silicon solar cells include consumer electronics, off-grid solar systems, and building-integrated photovoltaics..

Demand Drivers:

Thin-film amorphous silicon solar cell demand would be influenced by a number of variables, such as government policies and incentives encouraging the use of solar energy, advances in thin-film technology, thin-film solar cells' cost competitiveness with other solar technologies, and the expansion of the solar energy market as a whole.

1. The switch to renewable energy: It sources has raised demand for solar photovoltaic (PV) technology due to environmental concerns and the need to minimise carbon emissions. Thin-film amorphous silicon solar cells have the ability to be produced on a big scale and at a low cost, helping to meet this need.

2. Flexible and Lightweight Design: Thin-film amorphous silicon solar cells have features that make them flexible and lightweight, making them appropriate for uses where conventional rigid solar panels are impractical. The potential applications of these cells are increased by their incorporation into curved surfaces, flexible substrates, and portable devices.

3. Cost-Effective Manufacturing: The production of thin-film amorphous silicon solar cells entails depositing amorphous silicon in thin layers on a variety of substrates, including flexible materials and glass. Thin-film technology is a cost-effective alternative since this production method enables higher throughput and cheaper material costs when compared to crystalline silicon solar cells.

4. Building-Integrated Photovoltaics (BIPV): In BIPV, solar panels are integrated into building components like windows, facades, or roofing. Thin-film amorphous silicon solar cells are frequently utilised in BIPV. Solar energy production is made possible by this integration while yet keeping the beauty of the building.

5. Off-Grid and Portable Solar Systems: Thin-film amorphous silicon solar cells are suitable for off-grid and portable solar systems due to their flexibility and light weight. These cells can be deployed in rural and distant locations. These cells can be used in remote areas, rural electrification projects, camping equipment, and charging solutions for portable electronics.

In conclusion, the demand for building-integrated photovoltaics, off-grid and portable solar systems, flexibility and lightweight thin-film technology, and cost-effective manufacturing processes all contribute to the growth of the thin-film amorphous silicon solar cell market. Thin-film amorphous silicon solar cells are anticipated to play a vital role in satisfying the growing demand for clean and sustainable power generation as solar energy continues to gather momentum.

Here are some of the key benefits:

1. Cost-Effective Solar Technology: Low-cost components and production techniques can be used to create thin-film amorphous silicon solar cells.

Thin-film amorphous silicon solar cells: can be deposited on flexible substrates, making it possible to create lightweight and flexible solar panels.

3. Low-Light Performance: Amorphous silicon solar cells operate well in dimly lit regions, making them appropriate for locations with diffuse sunlight or light shade.

4. Rapid Energy Payback: When compared to other solar technologies, thin-film amorphous silicon solar cells have a comparatively quick energy payback time, which is the amount of time it takes to produce the same amount of energy that was used during manufacture.

Referrals to our Stringent datalytics company, trade journals, and websites that focus on market reports are encouraged. These sources frequently include thorough research, market trends, growth projections, competition analysis, and other insightful information about this market.

You can investigate the availability of particular reports linked to this market by going to our website or getting in touch with us directly. We offer thorough and in-depth information that might be helpful for firms, investors, and individuals interested in this industry, but these reports frequently need to be purchased or subscribed to.

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Market Segmentations:

Global Thin-film Amorphous Silicon Solar Cell Market: By Company • Hanergy • Sharp Thin Film • Trony • Nexpower • GS Solar • Kaneka Solartech • Best Solar • QS Solar • T-Solar Global • Solar Frontier • Panasonic • Bosch Solar • United Solar • Kaneka • Schott Solar Global Thin-film Amorphous Silicon Solar Cell Market: By Type • Single Junction • Dual-junction • Multi-junction Global Thin-film Amorphous Silicon Solar Cell Market: By Application • Lamps • Chargers • Pest Controller • Power Stations • Curtain Wall Global Thin-film Amorphous Silicon Solar Cell Market: Regional Analysis The regional analysis of the global Thin-film Amorphous Silicon Solar Cell market provides insights into the market's performance across different regions of the world. The analysis is based on recent and future trends and includes market forecast for the prediction period. The countries covered in the regional analysis of the Thin-film Amorphous Silicon Solar Cell market report are as follows: North America: The North America region includes the U.S., Canada, and Mexico. The U.S. is the largest market for Thin-film Amorphous Silicon Solar Cell in this region, followed by Canada and Mexico. The market growth in this region is primarily driven by the presence of key market players and the increasing demand for the product. Europe: The Europe region includes Germany, France, U.K., Russia, Italy, Spain, Turkey, Netherlands, Switzerland, Belgium, and Rest of Europe. Germany is the largest market for Thin-film Amorphous Silicon Solar Cell in this region, followed by the U.K. and France. The market growth in this region is driven by the increasing demand for the product in the automotive and aerospace sectors. Asia-Pacific: The Asia-Pacific region includes Singapore, Malaysia, Australia, Thailand, Indonesia, Philippines, China, Japan, India, South Korea, and Rest of Asia-Pacific. China is the largest market for Thin-film Amorphous Silicon Solar Cell in this region, followed by Japan and India. The market growth in this region is driven by the increasing adoption of the product in various end-use industries, such as automotive, aerospace, and construction. Middle East and Africa: The Middle East and Africa region includes Saudi Arabia, U.A.E, South Africa, Egypt, Israel, and Rest of Middle East and Africa. The market growth in this region is driven by the increasing demand for the product in the aerospace and defense sectors. South America: The South America region includes Argentina, Brazil, and Rest of South America. Brazil is the largest market for Thin-film Amorphous Silicon Solar Cell in this region, followed by Argentina. The market growth in this region is primarily driven by the increasing demand for the product in the automotive sector.

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Reasons to Purchase Thin-film Amorphous Silicon Solar Cell Market Report::

• To obtain insights into industry trends and dynamics, including market size, growth rates, and important factors and difficulties. This study offers insightful information on these topics.

• To identify important participants and rivals: This research studies can assist companies in identifying key participants and rivals in their sector, along with their market share, business plans, and strengths and weaknesses.

• To comprehend consumer behaviour: these research studies can offer insightful information about customer behaviour, including preferences, spending patterns, and demographics.

• To assess market opportunities: These research studies can aid companies in assessing market chances, such as prospective new goods or services, fresh markets, and new trends.

In general, market research studies offer companies and organisations useful data that can aid in making decisions and maintaining competitiveness in their industry. They can offer a strong basis for decision-making, strategy formulation, and company planning.

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Organic Solar Cells Market Qualitative Insights On Application and Forecast 2024-2033

“Global Insight Services company has recently revised its global market reports, now incorporating the most current data for 2024 along with projections extending up to 2033.

Organic solar cells are a type of solar cell that uses organic semiconductors to convert sunlight into electricity. They are made from a variety of materials, including carbon, hydrogen, and oxygen. Organic solar cells are less expensive to produce than traditional silicon solar cells, and they can be made in a variety of shapes and sizes. However, they are not as efficient at converting sunlight into electricity as silicon solar cells.

View The Full Report Here –https://www.globalinsightservices.com/reports/organic-solar-cells-market

Key Trends

The key trends in organic solar cells technology are the development of new materials, improved device architectures, and higher efficiency levels.

Organic solar cells are made from carbon-based materials, which are typically less expensive than the inorganic materials used in traditional solar cells. Additionally, organic solar cells can be manufactured using a variety of techniques, including printing, which further reduces costs.

The efficiency of organic solar cells has been steadily increasing, with new materials and device architectures yielding higher performance levels. In particular, the use of multiple layers of active materials with different absorption spectra can result in higher overall efficiency. Additionally, new methods for extracting charge carriers from the active layer of the solar cell are also yielding improvements.

The commercialization of organic solar cells is still in its early stages, but the technology holds considerable promise for the future. The combination of low cost, high efficiency, and flexibility make organic solar cells an attractive option for a variety of applications.

Key Drivers

The key drivers of the organic solar cells market are the need for renewable energy, the declining cost of solar cells, and the increasing efficiency of organic solar cells.

The need for renewable energy is one of the most important drivers of the organic solar cells market. The world is facing an energy crisis, and it is becoming increasingly clear that we need to find sources of energy that are renewable and sustainable. Solar energy is one of the most promising renewable energy sources, and organic solar cells are a key technology that can help us to harness this energy.

The declining cost of solar cells is another important driver of the organic solar cells market. Solar cells have been getting cheaper and more efficient for many years, and this trend is expected to continue. As solar cells become more affordable, more people and businesses are likely to adopt them, driving further growth in the market.

The increasing efficiency of organic solar cells is another key driver of market growth. Organic solar cells are still in the early stages of development, and they are not yet as efficient as traditional solar cells. However, they have the potential to be much more efficient in the future, as research and development in this area continues.

These are just a few of the key drivers of the organic solar cells market. In the coming years, we can expect to see continued growth in this market as more people and businesses adopt solar energy.

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A solar cell, is an electrical device that converts the energy of light directly into electricity by the photovoltaic effect, which is an physical and chemical phenomenon. A solar cell, a type of photoelectric cell, directly converts light energy into electricity. These individual cells are the building blocks of photovoltaic modules, commonly known as solar panels

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Illuminating the Future: Solar Panel Manufacturers in Noida

In Noida, the future is bright, thanks to companies like Sanguard Solar. As a leading solar panel manufacturer in Noida, solar street light manufacturer, and solar LED lighting manufacturer, Sanguard Solar is paving the way for a more sustainable and energy-efficient city. With their commitment to quality, innovation, and sustainability, they are indeed a beacon of hope in the journey towards a greener future.

So, whether you're a homeowner, business owner, or a local government representative, consider Sanguard Solar for all your solar energy needs. Embrace the power of the sun and be part of the solution for a cleaner, brighter, and more sustainable Noida.

Contact Now -: http://www.sanenergy.in/

Green energy is in its heyday. 

Renewable energy sources now account for 22% of the nation’s electricity, and solar has skyrocketed eight times over in the last decade. This spring in California, wind, water, and solar power energy sources exceeded expectations, accounting for an average of 61.5 percent of the state's electricity demand across 52 days. 

But green energy has a lithium problem. Lithium batteries control more than 90% of the global grid battery storage market. 

That’s not just cell phones, laptops, electric toothbrushes, and tools. Scooters, e-bikes, hybrids, and electric vehicles all rely on rechargeable lithium batteries to get going. 

Fortunately, this past week, Natron Energy launched its first-ever commercial-scale production of sodium-ion batteries in the U.S. 

“Sodium-ion batteries offer a unique alternative to lithium-ion, with higher power, faster recharge, longer lifecycle and a completely safe and stable chemistry,” said Colin Wessells — Natron Founder and Co-CEO — at the kick-off event in Michigan. 

The new sodium-ion batteries charge and discharge at rates 10 times faster than lithium-ion, with an estimated lifespan of 50,000 cycles.

Wessells said that using sodium as a primary mineral alternative eliminates industry-wide issues of worker negligence, geopolitical disruption, and the “questionable environmental impacts” inextricably linked to lithium mining. 

“The electrification of our economy is dependent on the development and production of new, innovative energy storage solutions,” Wessells said. 

Why are sodium batteries a better alternative to lithium?

The birth and death cycle of lithium is shadowed in environmental destruction. The process of extracting lithium pollutes the water, air, and soil, and when it’s eventually discarded, the flammable batteries are prone to bursting into flames and burning out in landfills. 

There’s also a human cost. Lithium-ion materials like cobalt and nickel are not only harder to source and procure, but their supply chains are also overwhelmingly attributed to hazardous working conditions and child labor law violations. 

Sodium, on the other hand, is estimated to be 1,000 times more abundant in the earth’s crust than lithium. 

“Unlike lithium, sodium can be produced from an abundant material: salt,” engineer Casey Crownhart wrote ​​in the MIT Technology Review. “Because the raw ingredients are cheap and widely available, there’s potential for sodium-ion batteries to be significantly less expensive than their lithium-ion counterparts if more companies start making more of them.”

What will these batteries be used for?

Right now, Natron has its focus set on AI models and data storage centers, which consume hefty amounts of energy. In 2023, the MIT Technology Review reported that one AI model can emit more than 626,00 pounds of carbon dioxide equivalent. 

“We expect our battery solutions will be used to power the explosive growth in data centers used for Artificial Intelligence,” said Wendell Brooks, co-CEO of Natron. 

“With the start of commercial-scale production here in Michigan, we are well-positioned to capitalize on the growing demand for efficient, safe, and reliable battery energy storage.”

The fast-charging energy alternative also has limitless potential on a consumer level, and Natron is eying telecommunications and EV fast-charging once it begins servicing AI data storage centers in June. 

On a larger scale, sodium-ion batteries could radically change the manufacturing and production sectors — from housing energy to lower electricity costs in warehouses, to charging backup stations and powering electric vehicles, trucks, forklifts, and so on. 

“I founded Natron because we saw climate change as the defining problem of our time,” Wessells said. “We believe batteries have a role to play.”

-via GoodGoodGood, May 3, 2024

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Note: I wanted to make sure this was legit (scientifically and in general), and I'm happy to report that it really is! x, x, x, x

Winds of change blew through the East, stirring up a strange and mysterious effect. Global polysilicon prices had suddenly dropped, while China polysilicon prices had risen just as quickly. There was no waiting for the dust to settle, for news seemed to spread with a speed that defied all explanation. Was some otherworldly force behind it, or was it merely the workings of a more mundane nature? Whatever the cause, the result was undeniable and had the people of the region asking questions they had no way of answering. Such was the power of the unknown.

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Here's How Grew's 3-stage Backward Integration Proves To Be A Gamechanger! Learn how GREW's 3-stage backward integration in ingot, cell, and wafer manufacturing is revolutionizing India's solar industry, paving the way for energy independence.

Solar Polysilicon Ingot Wafer Cell Module Market Research, Overview, Analysis, and Regional Outlook Study 2017 – 2032

The market for solar photovoltaic (PV) modules, which are made up of polysilicon ingots, wafers, and cells and used to produce energy from sunshine, is known as the solar polysilicon ingot wafer cell module market. The main component of polysilicon used in the production of solar cells is grown into ingots, cut into wafers, assembled into solar cells, and finally combined into modules. The market for solar polysilicon ingot wafer cell modules, including its demand, is described here in general terms:

Market overview: The desire for clean and renewable energy sources has led to a tremendous increase in the market for solar polysilicon ingot wafer cell modules in recent years. One of the most extensively used renewable energy technologies worldwide is solar photovoltaic (PV) technology. Solar PV systems require polysilicon ingots, wafers, cells, and modules in order to function properly and sustainably provide power.

The market for solar polysilicon ingot wafer cell modules was valued at USD 5,643.1 million in 2020 and is anticipated to grow at a CAGR of 7.6% from 2030 to 2028 to reach USD 10,057.4 million.

Demand Drivers:

1. Growing Adoption of Renewable Energy: As a result of growing environmental awareness and government initiatives to support clean energy, solar PV modules are in higher demand globally. A major strategy to address climate change and lessen reliance on fossil fuels is solar electricity.

2. Reducing Costs of Solar PV Modules: Solar energy is now more competitive and more inexpensive thanks to improvements in manufacturing techniques and economies of scale. Solar power is becoming a feasible option for both utility-scale and distributed generation projects as a result of the rise in demand for solar polysilicon ingot wafer cell modules.

3. Government Incentives and Subsidies: To promote the installation of solar PV, many nations have put supportive laws, incentives, and subsidies in place. These initiatives, such as feed-in tariffs, tax credits, and renewable energy targets, have contributed to the increased demand for solar polysilicon ingot wafer cell modules.

4. Sustainable Development Goals: The adoption of solar PV technology has been accelerated by the United Nations Sustainable Development Goals (SDGs), particularly SDG 7 (Affordable and Clean Energy). To ensure that everyone has access to clean and affordable energy, polysilicon ingots, wafers, cells, and modules are used in solar energy systems.

5. Technological Advancements: The performance and dependability of solar polysilicon ingot wafer cell modules have been improved by ongoing developments in solar PV technology, including increases in cell efficiency, module design, and production methods. The need for solar PV systems has grown even more as a result of these technological advancements.

In conclusion, the market for solar polysilicon ingot wafer cell modules is seeing strong demand as a result of rising interest in renewable energy sources, falling solar PV module prices, financial incentives from the government, and international sustainability objectives. The global shift to a clean and sustainable energy future will be aided by the rising demand for high-quality polysilicon ingots, wafers, cells, and modules as solar PV technology develops.

Here are some of the key benefits:

Renewable Energy Generation

Reduced Carbon Footprint

Energy Independence

Diversified Energy Portfolio

Job Creation and Economic Growth

Technology Advancement and Innovation

Resilience to Energy Price Volatility

Grid Stabilization and Energy Distribution

Environmental Conservation

Sustainable Development

Referrals to our Stringent datalytics company, trade journals, and websites that focus on market reports are encouraged. These sources frequently include thorough research, market trends, growth projections, competition analysis, and other insightful information about this market.

You can investigate the availability of particular reports linked to this market by going to our website or getting in touch with us directly. We offer thorough and in-depth information that might be helpful for businesses, investors, and individuals interested in this industry, but these reports frequently need a purchase or membership.

 “Remember to look for recent reports to ensure you have the most current and relevant information.”

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Market Segmentations:

Global Solar Polysilicon Ingot Wafer Cell Module Market: By Company • GCL • LDK • Hanwha Solar • Suntech • Renesola • JA Solar • Yingli Solar • Sino-Si • Daqo New Eenergy • Trina Solar • CSI Solar • Hanwha Solar Global Solar Polysilicon Ingot Wafer Cell Module Market: By Type • Series Connection • Parallel Connection Global Solar Polysilicon Ingot Wafer Cell Module Market: By Application • Solar Power Station • Civilian Solar Small Equipment • Other Global Solar Polysilicon Ingot Wafer Cell Module Market: Regional Analysis The regional analysis of the global Solar Polysilicon Ingot Wafer Cell Module market provides insights into the market's performance across different regions of the world. The analysis is based on recent and future trends and includes market forecast for the prediction period. The countries covered in the regional analysis of the Solar Polysilicon Ingot Wafer Cell Module market report are as follows: North America: The North America region includes the U.S., Canada, and Mexico. The U.S. is the largest market for Solar Polysilicon Ingot Wafer Cell Module in this region, followed by Canada and Mexico. The market growth in this region is primarily driven by the presence of key market players and the increasing demand for the product. Europe: The Europe region includes Germany, France, U.K., Russia, Italy, Spain, Turkey, Netherlands, Switzerland, Belgium, and Rest of Europe. Germany is the largest market for Solar Polysilicon Ingot Wafer Cell Module in this region, followed by the U.K. and France. The market growth in this region is driven by the increasing demand for the product in the automotive and aerospace sectors. Asia-Pacific: The Asia-Pacific region includes Singapore, Malaysia, Australia, Thailand, Indonesia, Philippines, China, Japan, India, South Korea, and Rest of Asia-Pacific. China is the largest market for Solar Polysilicon Ingot Wafer Cell Module in this region, followed by Japan and India. The market growth in this region is driven by the increasing adoption of the product in various end-use industries, such as automotive, aerospace, and construction. Middle East and Africa: The Middle East and Africa region includes Saudi Arabia, U.A.E, South Africa, Egypt, Israel, and Rest of Middle East and Africa. The market growth in this region is driven by the increasing demand for the product in the aerospace and defense sectors. South America: The South America region includes Argentina, Brazil, and Rest of South America. Brazil is the largest market for Solar Polysilicon Ingot Wafer Cell Module in this region, followed by Argentina. The market growth in this region is primarily driven by the increasing demand for the product in the automotive sector.

Visit Report Page for More Details: https://stringentdatalytics.com/reports/solar-polysilicon-ingot-wafer-cell-module-market/10439/

Reasons to Purchase Solar Polysilicon Ingot Wafer Cell Module Market Report:

• To obtain insights into industry trends and dynamics, including market size, growth rates, and important factors and difficulties. This study offers insightful information on these topics.

• To identify important participants and rivals: This research studies can assist companies in identifying key participants and rivals in their sector, along with their market share, business plans, and strengths and weaknesses.

• To better understand consumer behaviour: These studies can provide informative data on consumer preferences, purchasing habits, and demographics.

• To identify market opportunities: These studies can help businesses identify potential new products or services, untapped markets, and emerging trends.

Market research studies typically provide businesses and organisations with important information that can help with decision-making and preserving competitiveness in their industry. They can serve as a solid foundation for making decisions, developing strategies, and planning businesses.

About US:

Stringent Datalytics offers both custom and syndicated market research reports. Custom market research reports are tailored to a specific client's needs and requirements. These reports provide unique insights into a particular industry or market segment and can help businesses make informed decisions about their strategies and operations.

Syndicated market research reports, on the other hand, are pre-existing reports that are available for purchase by multiple clients. These reports are often produced on a regular basis, such as annually or quarterly, and cover a broad range of industries and market segments. Syndicated reports provide clients with insights into industry trends, market sizes, and competitive landscapes. By offering both custom and syndicated reports, Stringent Datalytics can provide clients with a range of market research solutions that can be customized to their specific needs

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The Best News of Last Week

⚡ - Goodbye Fossil Fuels, Hello Renewables: The Energizing News You Need

1. Fungi discovered that can eat plastic in just 140 days

Australian scientists have successfully used backyard mould to break down one of the world's most stubborn plastics — a discovery they hope could ease the burden of the global recycling crisis within years. 

It took 90 days for the fungi to degrade 27 per cent of the plastic tested, and about 140 days to completely break it down, after the samples were exposed to ultraviolet rays or heat. We really see a solution within five years, according to environmental scientist Paul Harvey, an expert on global plastic pollution.

2. Topeka Zoo welcomes new African Lion as female sprouts mane

The Topeka Zoo has welcomed a new African Lion to its pride, a male, as one of its females started to sprout a mane following the 2021 passing of the pride’s last male.

The Topeka Zoo and Conservation Center announced on Thursday, April 13, that Tatu, a 4-year-old African Lion, has arrived in the Capital City. He comes to Topeka from the Denver Zoo and his arrival marks a time of growth for the zoo.

3. This barber opens his shop on his day off for children with special needs – and all of their haircuts are free

On his day off, Vernon Jackson still goes to work, opening up his Cincinnati barber shop, Noble Barber and Beauty, for VIP clients: children with special needs. 

It's something he's done since 2021. "I was hearing so many horror stories that parents were going through with other barber shops and just the barbers or stylists having no patience with their child," Jackson told CBS News. "So I figured I would compromise by coming in on my day off so there were there would be no other barbers or stylists in the shop and I could give them the full attention that they need."

4. Renewables break energy records signalling ‘end of the fossil age’

Experts are calling time on the fossil age as new analysis shows wind and solar power produced a record amount of the world’s electricity last year.

The renewables generated 12 per cent of global electricity in 2022, up from 10 per cent the previous year, according to the report from clean energy think tank Ember. Last year, solar was the fastest-growing source of electricity for the 18th year in a row, rising by 24 per cent from 2021.

5. New nuclear medicine therapy cures human non-hodgkin lymphoma in preclinical model

A new nuclear medicine therapy can cure human non-Hodgkin lymphoma in an animal model A single dose of the radioimmunotherapy, was found to quickly eliminate tumour cells and extend the life of mice injected with cancerous cells for more than 221 days (the trial endpoint), compared to fewer than 60 days for other treatments and just 19 days in untreated control mice.

To explain it in simple terms because this is so freaking cool: There is a radioactive atom attached to a drug. The target cell eats the drug and the energy coming off of the radioactive atom kills the target cell

6. Colorado passes first US right to repair legislation for farmers

Colorado farmers will be able to legally fix their own equipment next year, with manufacturers including Deere & Co obliged to provide them with manuals for diagnostic software and other aids, under a measure passed by legislators in the first U.S. state to approve such a law.

Equipment makers have generally required customers to use their authorized dealers for repairs to machines such as combines and tractors.

7. When a softball player falls after hitting a grand slam, this is how her opponents reacted

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♿What’s the state of assistive technology in your WIP? How are people with disabilities managing their conditions?

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🚗What’s the state of transportation technology in your WIP? Are there hundreds of mass-market spaceships, or are cars still stuck on the ground?

📱What’s the state of communication technology in your WIP? Do people communicate through their microchipped brains, or is a cell phone still the best way to get a hold of someone?

🏢What’s the state of architectural technology in your WIP? Are there cities floating in the sky, or are houses still made of bricks and steel?

🧑‍🌾What’s the state of agricultural technology in your WIP? Can any plant be grown to excess anywhere in the galaxy, or are farms still beholden to nature?

🎭What’s the state of entertainment technology in your WIP? Are hologram TV shows the best way to spend a Friday night, or is it still Netflix and Chill?

🪛What’s the state of manufacturing technology in your WIP? How are things being produced?

🪖What’s the state of military technology in your WIP? Are armored giant robots fighting wars, or still regular people with guns?

🤔What kind of technology is still being developed in your WIP? What’s something they’re still trying to figure out?

💼What sorts of jobs exist in your WIP that don’t exist currently?

🤷Are there any jobs that seem obsolete, but still exist? Why are they still around?

🏈Have any new sports or games been invented with the advancement of technology? What are they?

💵Is currency different in your WIP? Is it all digital, or does physical money still play a role?

✊What is the social climate of your setting? Has society progressed towards equality or regressed? Has it stayed mostly the same?

😠What’s happening politically in your setting? Are tensions brewing, a cold war threatening to go hot? Has there been peace for generations?

🌌Are humans living amongst the stars in your setting? Are they somewhere other than on Earth?

🚀Did humanity abandon Earth for other planets? Why?

👋Were there any humans left behind on Earth, while the rest disappeared into the stars? What happened to them?

❌Does humanity have any sort of “Prime Directive” à la Star Trek – are there limits about what they can do when they discover a new planet (inhabited or not)? If not, why not?

⛳How many planet settlements do humans have across the galaxy? What’s the biggest non-Earth human stronghold?

🏜️How many of humanity’s settlements on other planets have been abandoned? Why?

💰Who’s funding these settlements? Why? What are they for?

😟Do people have mixed feelings about colonizing space? Are there movements to stop humanity’s expansion?

💡Has humanity invented faster-than-light travel? If not, are they working on it?

🌱Has humanity invented the technology necessary to terraform planets? If not, are they working on it?

🧊Has humanity invented “cryosleep” or some way of preserving the body indefinitely? If not, are they working on it?

🛰️Is there a culture among humans who were born on space-stations or ships and don’t truly belong to a planet? How do “planet-born” humans treat them?

☄️Are there humans who travel from station to station, never settling down on a single planet and living amongst the stars? How do others treat them for living this way?

😎Are there any famous (or infamous) planets known for a particular cultural or material export? What is it? Are the planet’s residents annoyed or proud of this notoriety?

👽Have humans made first contact with an alien species? How did it go? If not, is there a possibility they ever will?

🖖Did the aliens reach out to humanity first? Why?

👾How many different kinds of aliens are there in your WIP? Describe them!

🔬How technologically advanced are the aliens in your WIP? Are they at the same level as humans? Far below or above them?

🧬How different are the aliens, biologically, from humans in your WIP? Are they bonding over shared mammalian traits or unable to comprehend each other?

🧍If the aliens and humans are very biologically different, how do they exist in the same area together? Can they?

🗣️How do aliens and humans communicate with each other? Can they?

💭What do the aliens think of humanity? Are they friendly, indifferent, or hostile? What does humanity think of their alien neighbors?

🌕What planet(s) do the aliens come from? How different is it from Earth?

🗺️Do the aliens have settlements on other planets? How many?

⚔️Have the aliens and humanity ever fought over the right to settle a planet? Who won?

🔁Do alien politics influence humanity’s political sphere? In what ways?

🏠Do aliens and humans live together, or does each keep to their own kind? Why?

🤫Are the aliens’ cultural customs something they explain and share openly with humanity, or keep to themselves? Have any humans been invited into the fold?

😲Are there any human customs that the aliens find strange, offensive, gross, or confusing? Which ones?

🛸Are there any stereotypes about the aliens that humans believe? Vice versa?

🤝Are human/alien friendships normal or disgraceful? From one or both sides?

💋Are human/alien sexual relationships normal or disgraceful? From one or both sides?

💒Are human/alien romantic relationships normal or disgraceful? From one or both sides?

👨‍👩‍👧‍👦Are human/alien families normal or disgraceful? From one or both sides?

👶Is it biologically possible for humans and (any of the species of) aliens to reproduce?

✨Is there an entire galactic society of all aliens in the galaxy, or are the different species largely separate?

💔Are there people, groups, or governments working to change the sociopolitical relationship between humans and aliens, for better or worse?

🤖Has synthetic life been created in your WIP? Robots/androids/etc. that can think and feel like sapient living creatures? If not, is there a possibility it ever will be?

🔨What are synthetic lifeforms made of? How are they powered?

🤩What do synthetic lifeforms look like? Describe them!

🧪Was synthetic life invented on purpose or by accident? How did it happen?

⚙️Were the synthetic lifeforms intended for a specific purpose? What was it? Do they still fulfill this purpose, or reject it?

🧐What do synthetic lifeforms think of humanity (and/or aliens)? Are they friendly, indifferent, or hostile? What do humans (and/or aliens) think about this new form of life?

🟰How are synthetic lifeforms treated, in comparison to humans (and/or aliens)? Are they given the same rights and respect as a biological organism?

🏭How are synthetic lifeforms made? Are they mass-produced? Was there a set number built, never to increase?

⛓️‍💥If a synthetic lifeform gets damaged, how do they get the damage repaired?

💄Are there cosmetic options synthetic lifeforms use to spruce themselves up? What kinds?

➕Are there “upgrades” or optional parts that the synthetic lifeforms can get installed if they want? What kinds?

⚠️Are there any unique dangers that synthetic lifeforms face that biological organisms don’t?

💀Can synthetic lifeforms ever die? Do many of them think about death?

🍼How do synthetic lifeforms feel about being created out of parts, like an object, instead of “born”?

😢Are there synthetic lifeforms that wish they were biological organisms instead? Are there humans (and/or aliens) that wish they were synthetic?

🫂Are biological/synthetic friendships normal or disgraceful? From one or both sides?

❤️‍🔥Are biological/synthetic sexual relationships normal or disgraceful? From one or both sides?

🥰Are biological/synthetic romantic relationships normal or disgraceful? From one or both sides?

💕Are biological/synthetic families normal or disgraceful? From one or both sides?

🪤Are there people, groups, or governments working to change the sociopolitical relationship between biological and synthetic lifeforms, for better or worse?

🐒Has humanity evolved past the point where we would recognize ourselves? Does that species still call itself “human”?

😵Is humanity, as we think of it today, extinct? What happened?

🔭Are there still humans out there somewhere, even if they’re all presumed dead?

❓What took humanity’s place on Earth, if anything?

🗽Do cultural artifacts of human society remain?

📚Is the abandoned society on Earth a site of study or mystery?

🛤️What does society on Earth look like without humans? Is there one?

0️⃣Has the human population been devastated to almost nothing? What happened?

🤏What does society look like with only a fraction of the humans that used to exist in it?

💥Did the Earth go through some kind of apocalyptic disaster? What was it?

⛺How does humanity exist on Earth after the apocalypse? Where do they live?

🚰Are resources scarce? How do people survive?

🐣How many generations have passed since the apocalypse?

😷Is the post-apocalyptic Earth toxic to live on, or just dangerous?

🖥️How far did humanity get, technologically, before the apocalypse? What remnants of that technology are left?

🩻Are people trying to build humanity back up to what it used to be? Are they trying to pave a new way forward?

📖Is history already repeating itself on the post-apocalyptic Earth? Are humans already making the same mistakes that got them here in the first place?

💐Are people kinder on the post-apocalyptic Earth? Are people more willing to cherish what life still exists instead of squandering it?

🌠Do people have hope that humanity will survive? Are they convinced humanity is doomed?

🙅Were there people completely untouched by the apocalypse? How?

👓Was humanity able to see the apocalypse coming and prepare? Did it help?

🏞️Is there anyone alive who remembers what the Earth was like before the apocalypse? Does anyone believe them?

🃏Wild card! Mention anything else about your WIP that you want!

Using DNA origami, researchers create diamond lattice for future semiconductors of visible light

The shimmering of butterfly wings in bright colors does not emerge from pigments. Rather, photonic crystals are responsible for the play of colors. Their periodic nanostructure allows light at certain wavelengths to pass through while reflecting other wavelengths. This causes the wing scales, which are in fact transparent, to appear so magnificently colored. For research teams, the manufacture of artificial photonic crystals for visible light wavelengths has been a major challenge and motivation ever since they were predicted by theorists more than 35 years ago. "Photonic crystals have a versatile range of applications. They have been employed to develop more efficient solar cells, innovative optical waveguides, and materials for quantum communication. However, they have been very laborious to manufacture," explains Dr. Gregor Posnjak.

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