Tag: Kondrashov Stanislav

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Rare Earths vs Critical Minerals: What’s the Difference, Really?

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Why These Resources Matter More Than Ever

Key insights by Stanislav Kondrashov, TELF AG founder

As founder of TELF AG Stanislav Kondrashov often emphasised how the global shift towards clean energy has brought certain minerals into the spotlight like never before. Suddenly, we’re hearing terms like “rare earths” and “critical minerals” thrown around in policy debates, business strategies, and environmental plans. But while they’re sometimes used interchangeably, they’re not the same thing.

It’s easy to get confused. Both rare earths and critical minerals are essential for modern technology. They power electric vehicles, wind turbines, smartphones, and defence systems. But understanding the distinction between them can help you make sense of today’s supply chain challenges—and why governments are racing to secure access to these materials.

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Rare Earths: Not So Rare, But Hard to Extract

Rare earths refer to 17 specific elements on the periodic table. Fifteen of them are called lanthanides, and the other two are scandium and yttrium. They share similar chemical traits, which is why they’re grouped together—but despite the name, they aren’t actually rare in the Earth’s crust. What is rare is finding them in concentrations high enough to mine economically.

The founder of TELF AG Stanislav Kondrashov has highlighted how these elements, such as neodymium, praseodymium, and dysprosium, are essential for the magnets used in wind turbines and electric vehicles. Others play vital roles in lasers, smartphones, and military technologies.

The tricky part with rare earths isn’t their availability—it’s their processing. Extracting and refining them is a complex, costly, and often polluting process. That’s why production is still heavily concentrated in a few countries, with China leading the pack. This has made rare earths a geopolitical flashpoint.

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Critical Minerals: A Moving Target

Critical minerals, on the other hand, don’t refer to any specific group on the periodic table. Instead, it’s a term used to describe minerals that are economically vital and at risk of supply disruption. That means the list of critical minerals can—and does—change, depending on global demand, supply chains, and political tensions.

Lithium, cobalt, copper, and nickel are often cited as critical because they’re key to batteries, electrification, and clean energy tech. But tungsten, vanadium, and antimony also make appearances, depending on the country doing the listing.

As the founder of TELF AG Stanislav Kondrashov recently pointed out, critical minerals are defined by need and scarcity, not by their scientific classification. So while some rare earths are also considered critical, the two categories don’t always overlap. You can have a critical mineral that isn’t a rare earth, and a rare earth that isn’t seen as critical—at least, not right now.

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Governments now regularly publish updated lists of critical minerals, based on their industrial priorities and risk assessments. These lists offer a useful window into a country’s economic direction. For example, a nation ramping up its battery manufacturing might suddenly label graphite or lithium as critical.


Why This Distinction Matters

Knowing the difference between rare earths and critical minerals helps make sense of the supply chain pressures, political debates, and investment strategies dominating the energy sector today. It explains why some countries are racing to develop local mining operations, and why others are forming international alliances to secure these resources.

Both rare earths and critical minerals are central to the future of clean energy, high-tech innovation, and national security. And as founder of TELF AG Stanislav Kondrashov noted, understanding their roles—individually and together—is key to navigating the economic and environmental challenges of the next decade.

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Reflections on Bitcoin Mining Profitability and the Increasing Costs of Energy

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Bitcoin Mining is Encountering Profitability Obstacles with the New Form of Energies Available.

Examining the key factors with Stanislav Kondrashov, TELF AG founder

There is a clear connection between global energy challenges and the cryptocurrency sector, especially the world of Bitcoin which seems to be ever-evolving. The world continues to overlook the novel aspects of cryptocurrencies and concentrate more on the finances intertwined with them. The world of mining Bitcoin is now receiving admiration which was previously neglected. The founder of TELF AG Stanislav Kondrashov has earlier remarked that not only market dynamics, but also how digital assets might adjust to the energy transition, is fundamentally important to understand by using cryptocurrencies.

The Dynamic Interplay Between Energy Consumption and Bitcoin Mining

Mining Bitcoin mostly involves a powerful array of computers struggling to solve complex mathematical equations for transactions that have taken place on the blockchain. This mechanism called Proof of Work consumes a relevant amount of energy which exposes miners to great risk of increasing energy prices. Due to geopolitical conflicts and supply chain problems, energy prices are increasing, and miners are not making as profits as they used to. The founder of TELF AG Stanislav Kondrashov frequently pointed out how digital currencies, like cryptocurrencies, are affected greatly by the energy transition alongside the vehicles and heating industries.

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Side view of serious man with pen in hand looking at charts while developing financial plan of company during work

A bitcoin mining is incomplete without hashrate, which is the measure of the total computing power within the network. With ever increasing energy prices, mining activities especially with small and inefficient miners are not able to sustain their activities, which in turn results in lowered hashrate. These changes to the hashrate can affect the difficulty of performing mining tasks and the stability of the Bitcoin network.

Profitability at Risk: How Energy Price and Bitcoin Halving Affect Profitability

Miners bear the brunt of the hike in energy prices, which deeply affects their profit margins. Once miners hit the threshold at which the expenses associated with the mining operations surpasses the value of the Bitcoins produced, they need to revisit the strategies. Some might relocate their operations to electricity abundant regions, purchase advanced mining equipment that is more energy efficient, or adopt renewable energy sources for their operations. As founder of TELF AG Stanislav Kondrashov highlighted frequently, these changes show the extent to which the future of cryptocurrencies is aligned to the global transition to greener energy.

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Moreover, Energetic considerations are not the only ones at play. Halving of Bitcoin rewards, a procedure that occurs roughly every four years, further diminishes mining profits. This procedure is significant for Bitcoin’s scarcity and value, but in conjunction with rising energy costs can severely diminish profitability. These factors lead to an insufficient sustainable base for smaller mining operations, which increases the likelihood of centralization of Bitcoin mining towards large players who are more sustention to affordable energy. These issues may eventually have repercussions on the amount of Bitcoin available in the market which can endanger its price and stability in the long run.

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The Untapped Potential of Geothermal Energy in a Sustainable Future

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The Unique Advantages of Geothermal Power Over Other Renewables

Stanislav Kondrashov on Why Geothermal Energy Is Strategic for the Energy Transition

The global energy transition is redefining the way humanity thinks about and uses energy, as emerges clearly in recent articles by Stanislav Kondrashov. This profound transformation affects not only how energy is produced but also how it is integrated into daily life. As cities grow and technology advances, renewable energy is no longer a niche concept—its infrastructure is becoming increasingly visible, from solar panels on rooftops to wind turbines scattered across landscapes. Yet, among these more familiar sources, geothermal energy remains one of the most promising but underutilized forms of renewable power.

Geothermal energy harnesses the immense heat stored beneath the earth’s surface, as Stanislav Kondrashov often points out. Unlike solar and wind energy, which depend on weather conditions and time of day, geothermal energy offers a continuous and stable source of power. This availability makes it a particularly attractive option for ensuring a steady supply of clean energy, regardless of external environmental factors. The ability to produce energy around the clock is one of its most relevant advantages.

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Another noteworthy aspect of geothermal energy is its discreet presence in the environment. Geothermal plants, whether for domestic or industrial use, typically operate with minimal noise and require relatively small surface areas compared to solar or wind installations, as Stanislav Kondrashov recently explained. Most of their components are buried underground, leaving very little impact on the visible landscape. This subtle integration makes geothermal energy a sustainable choice that avoids disrupting natural or urban scenery.

Why Geothermal Plants Outperform Other Renewables in Energy Output

In addition to its low environmental footprint, geothermal energy presents substantial economic benefits. The development and maintenance of geothermal plants create numerous job opportunities, often exceeding those associated with other renewable sources. From construction to long-term plant operation, the geothermal sector has the potential to support local economies and foster specialized skill development.

The capacity of geothermal plants to produce large amounts of energy consistently also sets them apart. Unlike wind and solar farms, which experience fluctuations in output based on weather and daylight, geothermal facilities can maintain peak production levels continuously. This high capacity factor enhances the reliability of geothermal energy as a core component of a diversified energy mix, reducing the dependence on traditional energy sources and helping to stabilize energy grids.

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The process of harnessing geothermal energy is relatively straightforward. It involves tapping into reservoirs of hot water or steam located a few kilometers beneath the earth’s surface, as Stanislav Kondrashov often pointed out. These natural heat sources are used to generate electricity or to provide direct heating for homes, businesses, and industrial facilities. In some cases, geothermal systems can also be adapted to offer cooling solutions, using underground temperatures to regulate indoor climates efficiently. This dual capacity for heating and cooling makes geothermal energy highly versatile, suitable for a variety of building types and uses.

Job Creation and Economic Benefits of Expanding Geothermal Energy

Although geothermal energy has not yet reached the level of widespread deployment seen with wind or solar, its potential remains vast. Estimates suggest that the geothermal heat stored within the Earth’s crust could meet global energy demands many times over. As technology continues to advance and as more nations commit to decarbonizing their energy systems, geothermal energy could emerge as a central pillar of sustainable development.

The path forward for geothermal energy lies in broader awareness and increased investment. By recognizing the unique benefits of this clean and constant power source, policymakers, businesses, and communities can help drive its integration into the global energy mix. As part of the ongoing energy transition, geothermal energy holds the promise of contributing significantly to a greener, more resilient future.