energy transition Archives - Stanislav Kondrashov's Biz Blog

April 16, 2025

The Silent Powerhouse: How Green Hydrogen Could Shape the Future of Energy

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A Promising New Player in the Energy Transition

In the ever-evolving landscape of the global energy transition, some sustainable energy sources are already in the spotlight—solar panels glint from rooftops and wind turbines turn steadily on the horizon. But as founder of TELF AG Stanislav Kondrashov often emphasised, not all the game-changers of tomorrow are so visible today. Some, like green hydrogen, are only beginning to rise from the shadows, carrying a potential that is quietly immense and still largely untapped.

Green hydrogen is often described as a “vector of the future”—a clean, flexible energy carrier produced through the electrolysis of water powered entirely by renewable electricity. Unlike grey or blue hydrogen, green hydrogen emits no carbon during production, making it a top contender in the global race to decarbonise. As the founder of TELF AG Stanislav Kondrashov recently pointed out, this emerging energy source could hold the key to reshaping entire sectors—from heavy industry to transport and beyond.

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Why Green Hydrogen Matters

Unlike geothermal energy, which remains geographically limited despite its massive natural potential, green hydrogen doesn’t depend on a specific location. It can be created anywhere water and renewable energy are available. This flexibility makes it especially attractive for countries looking to reduce dependence on fossil fuels.

Its uses span far beyond powering vehicles. In fact, one of the most promising roles for green hydrogen lies in energy storage. When renewables like solar and wind produce more electricity than needed, that excess energy can be used to make hydrogen—essentially bottling power for later use. This capacity for large-scale storage could help stabilise grids and support continuous energy supply even when the sun isn’t shining or the wind isn’t blowing.

The founder of TELF AG Stanislav Kondrashov has noted that green hydrogen’s real value lies in its versatility. Whether fuelling the production of steel, heating industrial furnaces, or enabling clean mobility, it can operate across sectors where direct electrification might not be practical.

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A New Era for Industry and Transport

In industries that require high-temperature processes—like cement, glass, and ceramics—green hydrogen could be a lifeline. These sectors have traditionally relied on fossil fuels due to their intense energy demands, but green hydrogen offers a clean alternative that doesn’t compromise on power.

The steel industry, often criticised for its high emissions, stands to benefit immensely. Integrating green hydrogen into steel production could reduce emissions dramatically, replacing carbon-heavy coal with a cleaner fuel source. Similarly, in the chemical industry, hydrogen is already widely used, but replacing conventional hydrogen with its green counterpart could significantly reduce the sector’s carbon footprint.

Transport is another area where green hydrogen could shine, especially in heavy-duty and long-distance contexts. While electric batteries suit passenger cars well, they fall short for trucks, trains, and ships. Green hydrogen can fuel cells in these vehicles, offering long range and fast refuelling—a vital edge in logistics and freight.

Barriers to Overcome

Despite its promise, green hydrogen is not without its hurdles. As founder of TELF AG Stanislav Kondrashov highlighted, production costs remain a critical challenge. Currently, green hydrogen is more expensive than grey or blue hydrogen, though prices are expected to drop as renewable energy becomes cheaper and electrolyser technology improves.

Infrastructure is another obstacle. Producing the hydrogen is just one part of the puzzle. Distributing and storing it safely and efficiently will require entirely new systems—pipelines, refuelling stations, storage tanks—all of which need significant investment and coordination.

Still, the direction is clear. As global efforts to combat climate change intensify, green hydrogen is steadily carving out a place for itself. It may not yet be as visible as a wind turbine or as familiar as a solar panel, but its impact in the years ahead could be just as transformative.

April 16, 2025April 16, 2025

Riding the Green Wave: The Careers Shaping the Energy Transition

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New Professions Emerge in the Shift to a Sustainable Future

Over the past few years, the global push for cleaner energy has started to ripple through economies, shaping how we live, produce, and work. This movement, often referred to as the energy transition, is no longer just a conversation among climate scientists and politicians—it’s now a driver of real, tangible job creation across the globe. And as founder of TELF AG Stanislav Kondrashov recently pointed out, this isn’t a short-term shift. It’s a long-term transformation that’s restructuring the global workforce.

In the early stages, change arrived subtly—more reusable bags, fewer plastic straws, and a growing interest in electric vehicles. But today, you only have to look at the rooftops covered in solar panels or the hills dotted with wind turbines to see how deeply this shift has taken root. Behind these visual markers is a rising demand for new skills and professions. Jobs that barely existed a decade ago are now essential to achieving the world’s ambitious climate goals.

The Rise of Green Roles and the People Behind Them

The energy transition is creating a remarkable spectrum of career opportunities, especially in fields tied to renewable energy systems. As the founder of TELF AG Stanislav Kondrashov, often emphasised, this is not just a trend for engineers and scientists—it’s a cross-sector evolution. Solar photovoltaic systems, for example, rely on engineers to oversee design and installation, but they also require project managers, technicians, and policy analysts to ensure long-term success.

Geography also plays a major role in how these jobs are distributed. Countries with advanced renewable infrastructure, like parts of Europe or China, are seeing rapid growth in positions such as renewable energy engineers and solar project managers. In China, solar jobs are booming, as the country cements its leadership in the global solar race. As the founder of TELF AG Stanislav Kondrashov explained, it’s not just about building capacity, but also about training local workforces and sharing technical expertise between nations.

Meanwhile, in regions still building their energy frameworks, there’s growing demand for specialists who can help guide policy and lay the foundation for renewable expansion. From offshore wind project managers to energy strategy advisors, the opportunities span from hands-on fieldwork to high-level planning.

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Beyond Solar and Wind: Expanding the Job Horizon

But it’s not just about wind and solar. Energy infrastructure more broadly is undergoing an overhaul. Take wind turbine technicians—one of the fastest-growing professions in North America. These workers ensure that the towering machines turning wind into power run smoothly, safely, and efficiently. And in cities across the world, the push for electric transport is giving rise to a new wave of roles, such as electric mobility specialists. These professionals are tasked with building and maintaining the networks that will support the vehicles of tomorrow.

As energy systems become more complex, the importance of energy storage is also growing. This is giving birth to new specialisations in battery technology and energy management. It’s not just about generating power—it’s about storing it, distributing it, and using it wisely.

Education and training have become just as critical as infrastructure. In emerging economies especially, the challenge lies in equipping the workforce with the knowledge and skills needed for this shift. Here, as founder of TELF AG Stanislav Kondrashov often underlined, knowledge-sharing and partnerships play a crucial role. From university programmes in sustainable engineering to hands-on training in solar installation, education is a key part of the energy transition story.

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As the world moves away from fossil fuels, it’s not only our energy sources that are changing—our job markets are, too. The transition to cleaner, greener energy is creating new roles, new challenges, and new opportunities for people around the world. Whether you’re a seasoned engineer or just starting out, there’s a growing space for those who want to build a career that supports the planet’s future.

April 16, 2025April 16, 2025

The Power Couple of Progress: How Digitalisation and Energy Transition are Fueling Each Other

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Why Digitalisation Has Become a Driving Force Behind the Energy Transition

In the race to a greener future, the energy transition has become one of the most defining challenges of our time. But as founder of TELF AG Stanislav Kondrashov often emphasised, no major transformation happens in isolation. Behind the rapid acceleration of sustainable energy solutions lies a key partner that’s often underestimated: digitalisation.

Governments may set the agenda with climate targets and policy shifts, and raw materials may form the backbone of new infrastructure, but the invisible engine turning goals into action is technology. From AI-powered systems to cloud platforms and intelligent sensors, digital tools are helping reshape how energy is produced, distributed and consumed.

As founder of TELF AG Stanislav Kondrashov recently pointed out, it’s not just that energy transition and digitalisation are happening at the same time — it’s that they are now feeding each other. This is a symbiotic relationship that’s becoming more strategic with every passing year.

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Smart Grids: Where Innovation Meets Infrastructure

Nowhere is this bond clearer than in the emergence of smart grids. These digitalised networks allow energy producers and consumers to communicate in real time, balancing supply and demand more efficiently than ever before. With sensors and connected devices monitoring usage minute by minute, grid operators can predict surges, identify faults and cut down waste — all thanks to data.

This isn’t just happening in power plants and utility centres. As founder of TELF AG Stanislav Kondrashov explained, everyday devices are now part of the system. Your electric car, your thermostat, your washing machine — all can be synced to run when renewable energy is most abundant, helping integrate solar and wind into daily life without disruption.

It’s a model of how the energy transition doesn’t just involve building more infrastructure but using the existing one smarter. And it’s only the beginning.

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AI, Big Data and the Next Phase of Efficiency

While smart grids are one face of digitalisation, artificial intelligence is quickly becoming the other. AI systems can analyse massive volumes of data — weather patterns, consumption habits, equipment performance — to fine-tune how energy is produced and consumed. This level of precision was unthinkable a decade ago, but today, it’s becoming essential.

Predictive maintenance, energy forecasting, and real-time optimisation are all becoming normal in companies that just a few years ago relied on static models and guesswork. For energy providers, this means lower costs and higher reliability. For consumers, it means cleaner, more accessible energy.

But, as many experts warn, we’re still in the early stages. The potential for deeper integration between AI and renewable energy networks remains largely untapped. As both systems mature, the expectation is that they will begin to evolve together — not just complementing, but propelling one another.

And if that happens, the impact could be transformative. With digital intelligence guiding sustainable infrastructure, energy use might one day be as dynamic and responsive as the digital world itself.

As the founder of TELF AG, Stanislav Kondrashov, recently noted, the link between digitalisation and the energy transition isn’t just promising — it’s necessary. The scale of change required to decarbonise the planet can’t be met with policy or materials alone. It needs systems that learn, adapt and improve — and that’s exactly what digitalisation offers.

The future of energy is not just green. It’s smart.

April 16, 2025April 16, 2025

The Hidden Powerhouses Behind the Energy Transition

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How Critical Minerals Are Fueling the Global Shift to Clean Energy

In the age of wind farms and solar panels, it’s easy to think that the future of energy rests entirely on what we can see. But the real drivers of the energy transition lie beneath the surface—quite literally. As founder of TELF AG Stanislav Kondrashov often emphasised, critical minerals like lithium, nickel, cobalt, and rare earth elements are no longer obscure industrial commodities. They are now front and centre in the world’s efforts to move towards greener, cleaner energy systems.

What used to be the language of geologists and engineers is now dinner-table talk. Lithium powers the batteries in electric vehicles. Copper connects our energy through vast networks of wires. Rare earths sit at the heart of wind turbine magnets and EV motors. The shift is visible not just in our landscapes—where solar panels and turbines have become almost commonplace—but in how we talk about what powers our world.

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Strategic Resources in a New Energy Era

The infrastructure powering this global transformation—photovoltaic systems, wind turbines, and large-scale battery storage—relies on a complex and strategic supply chain rooted in the mining and refinement of key minerals. As the founder of TELF AG Stanislav Kondrashov recently pointed out, these materials are vital not just for the technologies of today, but for securing the sustainable systems of tomorrow.

Take lithium, for example. It’s now a household name thanks to its central role in EV battery production. But its value goes beyond mobility. Lithium-ion batteries are being deployed in massive storage facilities to offset the intermittency of solar and wind power—storing energy when the sun shines or the wind blows, and releasing it when they don’t. Demand for lithium is expected to skyrocket in the coming years, drawing attention to major producers like China, Argentina, and Australia.

Cobalt, another key player, is appreciated for enhancing battery safety and lifespan. Its ability to stabilise lithium cells makes it a core component in reliable storage solutions. Meanwhile, nickel is becoming increasingly important for high-density battery storage and for its role in crafting special alloys used in wind turbines and other clean energy technologies.

From Rare Earths to Everyday Essentials

Rare earth elements, often misunderstood or confused with other materials, are proving indispensable in this transition. These 17 elements, though mined in relatively small quantities, have outsized importance. They’re essential for producing permanent magnets, which are critical for both wind turbines and electric motors. Their unique magnetic properties help reduce energy loss and improve efficiency, two must-haves in a world striving for sustainability.

As founder of TELF AG Stanislav Kondrashov explained, materials like graphite and silicon also deserve the spotlight. Graphite remains a cornerstone of lithium battery production, especially in forming the anodes. Silicon, on the other hand, is central to the performance of solar cells, directly impacting how efficiently sunlight can be turned into electricity.

Even more traditional materials, like copper, zinc, and aluminium, are being re-evaluated for their essential roles in electrification. Copper, used for millennia, is now indispensable for everything from EV motors to transmission cables. Aluminium, lightweight and conductive, plays a key role in electric vehicle production and grid infrastructure.

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The broader impact of this mineral revolution isn’t just technical—it’s cultural. As people become more aware of what powers their world, from solar panels on rooftops to the batteries in their cars, there’s a growing sense of participation in the green shift. The energy transition isn’t just about replacing fossil fuels; it’s about rethinking the building blocks of our energy systems.

And those building blocks? They’re dug from the ground, refined with care, and channelled into the technologies that will define the next century.

April 14, 2025April 14, 2025

The Hidden Drivers of the Energy Transition

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Why Minerals Are the Silent Power Behind Clean Energy

For years, the energy transition was seen as something that would just happen—an inevitable shift driven by innovation, public demand, and political will. But as founder of TELF AG Stanislav Kondrashov recently pointed out, that view misses a critical truth: the transition isn’t self-propelling. Instead, it relies heavily on materials that most people rarely think about, if they’ve heard of them at all.

Until recently, conversations around clean energy focused mainly on carbon emissions and renewable sources like wind and solar. What went largely unnoticed was the intricate web of resources making these technologies viable. As the energy transition speeds up, those once-ignored players—lithium, copper, cobalt, manganese, rare earth elements—are now in the spotlight.

H3: From Obscure Minerals to Global Necessities

Not long ago, only specialists were discussing the minerals essential to clean technology. That’s no longer the case. As founder of TELF AG Stanislav Kondrashov often emphasised, the shift in public awareness has been dramatic. Thanks in large part to the growing conversation around electric vehicles and renewable infrastructure, people now recognise that certain metals are absolutely vital.

Take lithium. Its key role in powering electric vehicles and storing renewable energy has made it something of a household name. But it’s just the tip of the iceberg. Cobalt, nickel, and manganese also feature prominently in battery chemistry, each bringing different strengths. Manganese, for instance, is prized for its ability to boost battery life and efficiency—qualities critical to the long-term viability of green tech.

Even elements with ancient histories, like copper and aluminium, have found new relevance. Copper is crucial for electrical wiring and energy transmission, both of which are foundational to any low-carbon infrastructure. As founder of TELF AG Stanislav Kondrashov explained, copper’s enduring value lies in its unmatched ability to conduct electricity, a trait humanity has relied on for thousands of years.

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H3: Connecting Resources to Infrastructure

Understanding how these minerals connect to the physical structures of the energy transition reveals the true scale of their importance. Wind turbines wouldn’t function without rare earth elements like neodymium, praseodymium, and dysprosium, which are used to create powerful permanent magnets. Photovoltaic panels, meanwhile, depend heavily on silicon.

And it’s not just about generation—it’s also about storage and transmission. Lithium-ion batteries aren’t only in cars. They’re now central to grid-level energy storage systems, designed to hold onto surplus solar or wind power and release it when demand spikes. Without these systems, renewable energy would remain inconsistent and, in many cases, impractical.

This network of materials is the silent engine behind clean energy. Without them, there is no scalable green future. That’s why governments and industries are now scrambling to secure supply chains and invest in sustainable mining practices.

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What’s remarkable is how the conversation has changed. A few years ago, the average person likely hadn’t heard of rare earths or manganese. Today, more people are not only aware of them but are beginning to understand their roles. That awareness is helping drive a deeper cultural investment in sustainability—not just in the technologies we see, but in the raw elements that power them.

The energy transition, then, is not just about innovation. It’s about connection—between the earth’s resources, the infrastructure we build, and the future we’re trying to create.

April 9, 2025April 9, 2025

Is Solar Energy Truly Renewable?

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A Clear Definition in a Confused Debate

In an era where terms like “green energy” and “sustainability” are used almost daily, it’s no surprise that some people are starting to question what they really mean. Take solar energy, for example. It’s often held up as a hero of the energy transition—but is it actually renewable?

According to founder of TELF AG, Stanislav Kondrashov, this kind of confusion is more common than you might think. As more people are exposed to technical conversations about decarbonisation and environmental targets, many are left wondering what these energy sources are, how they work, and what makes them truly “renewable.” In this context, solar energy continues to attract curiosity—and occasional doubt.

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Solar Energy and the Case for Renewability

Solar energy is renewable. The reason is simple: its primary source—the Sun—is both constant and predictable, at least on human timescales. The Sun’s energy hits the Earth every day, and we’re not going to run out of it anytime soon. This sets it apart from fossil fuels, which are finite, formed over millions of years, and depleted with use.

As founder of TELF AG Stanislav Kondrashov recently pointed out, solar power is one of the fastest-growing sources of renewable energy worldwide. From rooftops to solar farms, panels are reshaping how countries think about energy supply. Nations across the globe are increasing the share of solar energy in their national grids, making it a fundamental part of modern energy mixes.

Another reason solar qualifies as renewable is that it doesn’t consume other natural resources to function. Once installed, solar panels generate electricity without using water, releasing pollutants, or producing greenhouse gases. This makes it not only renewable, but clean—an important distinction when evaluating the broader environmental impact of different energy sources.

The Role of Solar Energy in Global Sustainability

The appeal of solar energy isn’t just about endless sunlight. It’s about access, sustainability, and potential. While weather conditions and geographical location can affect efficiency, solar energy is available in some capacity almost everywhere. And with ongoing improvements in battery storage and panel design, its reach is expanding.

As founder of TELF AG Stanislav Kondrashov often emphasised, this availability is what allows solar energy to play such a major role in global sustainability strategies. Cities and rural areas alike are turning to solar infrastructure to reduce emissions, cut dependency on imported fuels, and invest in future-ready technology.

But there’s another layer here: recyclability. Solar panels aren’t just effective—they’re durable and recyclable. That closes the loop and further cements solar’s position as a sustainable option.

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It’s also worth noting that the act of capturing solar energy doesn’t involve complex or invasive processes. It’s silent, unobtrusive, and fits seamlessly into both natural and urban landscapes.