Science

In January 2025, physicists from CERN and MIT joined forces to create the first-ever gravitational antenna—a device that transmits information using modulated gravitational waves. Unlike radio or light, these waves pass through any obstacle—planets, stars, black holes—without distortion or delay.

The technology is based on next-generation quantum interferometers capable of detecting spacetime fluctuations with an amplitude of 10⁻²¹ meters—the equivalent of measuring the change in distance from Earth to Alpha Centauri with an accuracy of a human hair. Transmission uses an array of rotating superconducting rotors, creating controlled “pulsations” of the gravitational field.

The first message was sent from Geneva to Tokyo—through the Earth. The transmission time was 0.04 seconds. It contained just three words: “Contact established.” But this is the beginning of a new era of communications. In the future, gravitational links will allow us to control probes beyond the event horizon of black holes and coordinate colonies on Mars without delay.

The advantages are enormous. The signal cannot be intercepted, spoofed, or blocked. It does not produce electromagnetic radiation that is hazardous to health. And it works in conditions where radio is silent—for example, inside nuclear reactors or in deep mines.

NASA is already testing a miniature version of the antenna for satellites. The first “gravitational internet” between the Moon and Earth is planned for 2026.

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In March 2024, scientists from Stanford and Singapore presented the world’s first bioplastic synthesized directly from carbon dioxide and water using genetically modified bacteria. The process mimics photosynthesis, but instead of sugar, it produces polyhydroxyalkanoates (PHA) – a fully biodegradable plastic that decomposes in soil within six weeks.

The bacteria, dubbed “CarboEaters,” were engineered using CRISPR-Cas12d, which allowed them to incorporate a “factory” for assembling polymer chains into their DNA. They operate in photobioreactors under sunlight, consuming CO₂ from the atmosphere. One cubic meter of reactor captures 2 tons of CO₂ per year and produces 1.5 tons of plastic.

The plastic has all the properties of traditional polypropylene: it is strong, flexible, and heat-resistant. But it’s also non-toxic, edible to microorganisms, and can even be used in medicine for absorbable sutures. It’s already used in IKEA packaging and L’Oréal cosmetics.

Scaling is progressing rapidly. The first industrial plant with a capacity of 10,000 tons per year has been built in Dubai. It’s powered by solar energy and removes CO₂ from the air through direct capture. The cost is $1.20 per kilogram, comparable to petroleum-based plastic.

The most revolutionary aspect is its recycling. Packaging made from this plastic can be buried in the garden—after a month, only water, CO₂, and humus will remain. And if thrown into the ocean, it will decompose in 12 weeks without harming the ecosystem.

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In 2024, a Boston-based startup, NeuroPharm AI, presented a system capable of developing a new cancer drug molecule, testing it in a simulation, and proposing a clinical protocol in 48 hours. Previously, this process took 10-15 years and cost $2.6 billion. Now, it takes two days and costs $40,000. It is based on a hybrid neural network that combines deep learning models with quantum calculations of protein structure.

The system analyzed 150 million known biological interactions and identified a pattern missed by humans: some tumors use “molecular decoys” to suppress the immune response. The AI ​​proposed a molecule that blocks these decoys. The drug, called “ImunoKey,” has already completed Phase I clinical trials, with 98% of patients experiencing no side effects.

The key advantage is personalization. Artificial intelligence analyzes a patient’s genome, microbiome, and lifestyle to create a unique medicine. In 2025, the first “micropharm” opened in Switzerland—a garage-sized factory where AI controls drug synthesis in real time. A patient comes in the morning and leaves in the afternoon with a medicine created during their tea break.

The technology is already saving lives. In Japan, AI has developed a cure for a rare form of leukemia affecting children. Previously, the survival rate was 12%. After the new drug, it’s 89%. The WHO has included this approach in its global cancer program.

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In 2024, a Japanese-Swiss team of scientists created the world’s first efficient artificial photosynthetic reactor, capable of converting sunlight, water, and carbon dioxide into liquid fuel with an efficiency of 23%—almost three times higher than the best solar panels. The device mimics the plant process, but instead of chlorophyll, it uses nanostructured catalysts based on cobalt and copper, which capture solar energy and “cross-link” molecules into hydrocarbons.

The main innovation is sustainability. Early prototypes deteriorated within hours. The new reactor operates for six months without losing efficiency. This is made possible by a self-cleaning membrane that prevents the accumulation of byproducts. The system operates even in cloudy weather, using not only visible light but also infrared radiation.

Practical applications have already been launched: a pilot plant producing “solar kerosene” for aviation has been built in Dubai. It is completely CO₂ neutral: the emissions from burning the fuel equal the amount absorbed from the atmosphere during its production. Lufthansa and Emirates have signed contracts to purchase this fuel starting in 2026.

The invention is also revolutionary on a domestic scale. A microwave-sized mini-reactor can provide a family of four not only with electricity but also with fuel for their car. It connects to the plumbing and ventilation systems, extracting CO₂ from the air in the home. The device costs $1,200, and the payback period is less than two years.

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In early 2025, a team of physicists from the Universities of Oxford and Zurich announced the creation of the world’s first stable quantum node capable of controlling the local flow of time. This isn’t a Hollywood time machine, but a device that slows down temporal processes at the microscopic level with an accuracy of 10⁻¹⁵ seconds. The essence of the invention lies in a quantum “feedback loop,” where entangled particles create a closed causal loop, allowing an event to be temporarily “isolated” from the external flow of time.

This discovery was made possible by a new type of quantum memory based on diamond vacancies. The scientists were able to maintain a quantum state for more than 10 minutes—a record previously thought impossible. This stability made it possible to conduct an experiment in which photons “returned” into the past for several nanoseconds to interact with themselves. The effect was confirmed by independent laboratories in Tokyo and California.

Practical applications are already emerging in medicine: quantum sensors based on this technology can detect the smallest changes in neural activity in the brain, predicting epileptic seizures up to 30 seconds before they begin. For patients, this offers the opportunity to stop a seizure early with a neurostimulator. In the future, such systems could prevent strokes and heart attacks at the incipient stage.

In computing, the new approach opens the way to “temporal algorithms”—programs that can “look into” their own execution and correct errors before they occur. This radically reduces the energy consumption of quantum computers and increases their reliability. IBM has already announced plans to integrate such algorithms into its processors by 2027.

What’s particularly striking are the philosophical implications. If a quantum system can interact with its own past, then the concept of “cause and effect” loses its absoluteness. This doesn’t violate the laws of physics, but it does force us to reconsider the fundamental logic on which science is built. Nobel laureate Roger Penrose called this “the most important discovery since general relativity.”

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