Toggle light / dark theme

The World in 2050: 10 Future Technologies That Will Change Everything | AI Documentary 4K

🚀 Subscribe to Beyond Tomorrow AI for cinematic AI documentaries about the future of technology.

What will the world look like in 2050? Discover 10 future technologies that could change humanity forever.
From Artificial Intelligence and humanoid robots to quantum computing, fusion energy, flying cars, and Moon colonies—this cinematic AI documentary explores the future of our world.

Welcome to the world of 2050! Explore 10 incredible future technologies that could transform medicine, artificial intelligence, space exploration, transportation, robotics, and everyday life. Discover how tomorrow’s innovations may change the world forever.
🌍 What will the world look like in 2050?

Artificial Intelligence, humanoid robots, flying cars, Moon colonies, quantum computing, fusion energy, and space exploration are transforming our future.

In this cinematic documentary, discover the 10 future technologies that could change everything.

⏱ CHAPTERS

Graphene nanoribbons survive gamma radiation, revealing potential sensors for fusion reactors

University of Arizona researchers have demonstrated a promising new application for graphene nanoribbons, a nanoscale semiconductor material with the potential to withstand extreme environments. The team’s findings could help clear a key hurdle to bringing fusion energy to the electric grid.

For the proof-of-concept study, published in the journal ACS Applied Materials & Interfaces, the researchers integrated the nanoribbons, known as GNRs, into semiconductor devices and exposed them to gamma radiation. Their results suggest that the ribbons could serve as radiation sensors for fusion reactors and in deep space, where intense radiation challenges existing technologies and close monitoring of material degradation could help keep critical systems operating reliably.

“The devices survive the exposure and still respond, but their electrical performance changes dramatically,” said principal investigator Zafer Mutlu, an assistant professor of materials science and engineering at the University of Arizona College of Engineering. “That’s exactly the behavior we want from a sensor.”

Single fission experiment maps excess gamma rays from more than a dozen unstable nuclei

In a single experiment, physicists have measured the “excess” emission of high-energy gamma rays from more than a dozen heavy, unstable atomic nuclei. Mapping the gamma-ray emissions of so many isotopes produced in nuclear fission marks an important step toward a better understanding of one of the key phenomena in modern nuclear physics: the fission process itself.

Why do excited heavy nuclei produced in fission appear to emit excessive amounts of particularly energetic gamma radiation? New clues to this long-standing question have emerged from an international experiment conducted at the GANIL accelerator facility in Caen, northern France. Here, a beryllium-9 target was bombarded with uranium-238 ions, producing unstable curium-247 nuclei that rapidly underwent fission into two lighter fragments.

By combining unique experimental techniques, researchers were able—for the first time within a single experiment—to collect data on high-energy gamma-ray emissions from more than a dozen heavy, unstable isotopes. The first results of the experiment, to which the Institute of Nuclear Physics of the Polish Academy of Sciences (IFJ PAN) in Krakow made a significant contribution, have just been published in Physics Letters B.

Quantum Computers Identify Nuclear Fusion Fuel in Major First

A major barrier to harnessing energy via nuclear fusion is the fuel source.

Most proposed fusion reactors (the donut-shaped tokamak reactors) are powered by the fusion of tritium and deuterium.

Both are isotopes of hydrogen, but tritium is radioactive, and deuterium is stable.

Solving a 30-year-old puzzle about a mysterious superconducting material

A material made from yttrium, barium and copper oxide (better known as YBCO) has intrigued scientists since its discovery in 1987, largely because it retains its superconductive properties at a higher-than-normal temperature. However, it is extremely brittle, which makes it tricky to put to practical use.

But researchers can still learn much from it. For instance, its unusual properties can provide insight into designing possible room-temperature superconductors —that is, materials that conduct electricity with no resistance at room temperature. Doing so would have a huge impact on power transmission, medical imaging and fusion reactor magnets.

One thing about YBCO that has mystified researchers is that doping it with praseodymium, a rare earth element, completely kills the material’s superconductive properties. That is unusual because adding other rare earth elements to YBCO does not have the same effect.

White-beam neutron device unlocks precise control of twisted quantum waves

CANISIUS is the official name of the new spin-echo neutron interferometer developed at Atominstitut, TU Wien. It enables precise control of neutron waves, something that was previously impossible.

Neutrons cannot be imagined as tiny spheres; they have wave properties similar to light. This was spectacularly demonstrated in 1974 at the nuclear reactor of the Atominstitut—and it was precisely here that researchers succeeded in exploiting this wave nature of neutrons in a novel way: A measuring device was developed that can use the angular momentum of neutrons in a particularly clever way for experiments. Not only the intrinsic angular momentum—the spin—but also the orbital angular momentum, which is related to the waveform of the neutron, can be adjusted.

The research is published in the journal Review of Scientific Instruments.

Metals’ atomic arrangement can create ‘corrosion highways’ in nuclear reactors

Nuclear reactors are traditionally powered with dense fuel rods that can produce about 1 gigawatt of carbon-free electricity, enough to power about 100,000,000 lightbulbs. Newer power plant designs using molten salt for cooling instead of the water found in traditional reactors could offer better efficiency and stability, but they face a problem—the extreme chemical environment created by the molten salt can corrode the metal comprising the reactor.

A team led by engineers at Penn State found that adjusting the subtle atomic arrangement of structural metals can significantly affect the rate and extent of this corrosion, even with identical baseline chemical compositions. They did this by creating a series of reactive simulations to isolate and study this corrosion mechanism. Their findings are available online ahead of publication in the August issue of Corrosion Science.

Quantum computers model nine fusion fuel material configurations for first time

A team of scientists from Oak Ridge National Laboratory, Cleveland Clinic and IBM has calculated nine molecular configurations of a promising material to produce fuel for fusion energy—the first known instance of such computations on quantum computers.

Such calculations, demonstrated in a new paper published on the arXiv preprint server, are computationally challenging for classical computers to scale when working alone. They are a fundamental step toward optimizing the production and extraction of tritium—an extremely rare material in nature that is necessary to produce fusion energy with most of the proposed machines. Ensuring adequate supplies of tritium has long been a barrier to realizing the promise of clean, abundant energy from fusion power plants, and solving this issue is a key objective of the U.S. Department of Energy’s Genesis Mission.

Quantum computers are well-suited to computing the atomic-level chemistry of a liquid salt that contains fluorine, lithium and beryllium (FLiBe), one of the leading candidate materials for extracting tritium fuel in fusion reactors. To compute different configurations of clusters of FLiBe, the team used the same quantum-centric supercomputing techniques now being applied to 12,635-atom protein simulations with Cleveland Clinic. These methods can calculate the quantum behavior of electrons in complex materials, complementing and enhancing the capabilities of classical supercomputers and algorithms.

Detecting neutron sources by borrowing inference tools from cosmology

Neutron sources can be directly identified from measured spectra rather than proxies using inference tools adapted from cosmology, according to a University of Michigan Engineering study published in Physical Review Applied. The method can improve nuclear security by helping intercept materials at ports or borders or guide first responders during emergency response.

Directly detecting and characterizing a neutron source remains a challenge because most nuclear materials emit neutrons with energy patterns, called neutron spectra, that look similar to one another—whether from a benign industrial isotope or fissile material.

“This problem sits at the intersection of fundamental physics, statistics and real-world nuclear security. There is a very practical need to identify unknown neutron-emitting materials, but there is also a deep scientific challenge: How do you extract reliable information from signals that are weak, noisy and highly similar?” said David Breitenmoser, a postdoctoral research fellow of nuclear engineering and radiological sciences at U-M and lead author of the study.

Startup activates nuclear microreactor live on stage to power an Nvidia RTX Spark desktop PC — firm working with Nvidia to build a 30MW closed loop AI factory that doesn’t use local water

Will this solve the AI boom’s power and water bottlenecks?

/* */