Future technological ideas that will change our world. Like it or not, technology is developing rapidly, each year offering new innovations and revolutionary projects. Some of the very sharp minded s are creating the next future technology that will completely change our lives. It seems that scientific progress is steady, but over the past half century we have experienced a period of tremendous technological improvement.
Now there are innovations coming straight from the pages of science fiction. Whether it’s a robot that can read minds, artificial intelligence that can create its own images, holograms, bionic eyes, or other amazing technologies, much can be expected from the world of tomorrow’s technology. Below we have selected some of the biggest and most interesting ideas.
As artificial intelligence continues to perform as well as humans, there is a new industry to add to the list – the world of art. Researchers from OpenAI have created software that is able to create images only from formulated instructions.
Enter “the dog in the cowboy hat singing in the rain” and you’ll get a variety of completely original images that fit this description. You can even choose in what style your request will be sent. However, the technology is not perfect and it still has problems, for example when we give bad tips on developing cartoon characters.
The technology, known as Dall-E, is its second iteration, and the team behind it plans to continue its development. In the future, we could see that this technology will be used to create art exhibitions, for companies to get quick original illustrations or, of course, to revolutionize the way we create memes online.
In recent years, the use of brain-reading technology is no longer a fantasy. One of the most interesting and practical applications we’ve seen tested so far comes from researchers at the Swiss Federal Institute of Technology in Lausanne (EPFL).
Thanks to machine learning algorithms, robotic arms, and a brain-computer interface, these researchers were able to create a means to interact with the world of patients with tetraplegia (those who cannot move their upper or lower body).
In testing the robotic arm will perform simple tasks such as moving around obstacles. The algorithm then interprets signals from the brain using the EEG cap and automatically determines whether the hand has performed a movement the brain thinks is wrong, such as moving too close to an obstacle or too fast.
Over time, algorithms can adapt to individual preferences and brain signals. In the future, this could lead to brain-operated wheelchairs, or assistive machines for patients with tetraplegia.
3D printing is an industry that promises everything from inexpensive home construction to affordable durable armor, but one of the most exciting applications of this technology is the creation of 3D printed bones.
Ossiform specializes in medical 3D printing, allowing patients to replace various bones with tricalcium phosphate, a material with properties similar to human bone.
Using these 3D printed dice is surprisingly easy. An MRI can be performed in a hospital, which is then sent to Ossiform, which creates a 3D model of the implant required for a particular patient. The surgeon accepts the design and then, once printed, can be used in surgery.
The uniqueness of this 3D printed bone is that due to the use of tricalcium phosphate, the body will process the implant into vascularized bone. This means that they will completely restore the function of the bone it replaces. To achieve the best possible integration, the implant has a porous structure and has large pores and channels for cells to attach to and reshape the bone.
Holograms have filled science fiction, film, and culture for years, and even though they exist, they are difficult to achieve, especially on a large scale. However, a potential technology that can change this is holobrix .
Developed by researchers from Cambridge University and Disney Research, galaxies are a way to combine multiple holograms to produce large, seamless 3D images.
The problem with most holograms today is the amount of data they need to create, especially if they are created on a large scale. A normal HD display for 2D image creation takes about 3 GB per second. A hologram of the same size and resolution would be close to 3 TB per second, which is a huge amount of data.
To overcome this, holograms provide individual parts of one large holographic image, which greatly reduces the amount of data required. This could eventually lead to the use of holograms in everyday consumer entertainment such as movies, games and digital displays.
Years of wearable technology have given new features to the accessories and clothes we wear every day. One promising way is to give clothes to the ear or at least the same capacity as the ear.
Researchers at the Massachusetts Institute of Technology have created a fabric that can recognize palpitations, clapping of hands or even very faint sounds. The team suggests that it could be used to apply technology to the blind, be used in buildings to detect cracks or deformation, or even be woven into fishing nets to detect fish sounds.
Currently the materials used are thick, and work is continuing, but they hope to be able to put them to consumer use in the next few years.
You’ve heard of cultured “meat” and Wagyu steak grown cell by cell in the laboratory, but what about other animal products? A growing number of biotech companies around the world are researching laboratory-produced dairy products, including milk, ice cream, cheese, and eggs. And more than one person thought they hacked it.
The dairy industry is not environmentally friendly, even close. It is responsible for 4 percent of the world’s carbon emissions, which is more than air travel and shipping combined, and there is a growing demand for more environmentally friendly sparks that can be poured into our teacups and porridge.
Compared to meat, milk is less difficult to make in the laboratory. Instead of growing them from stem cells, most researchers try to produce them during fermentation in an attempt to produce whey and casein proteins. Several products already exist on the US market from companies such as Perfect Day, with ongoing work aiming to reproduce the taste sensations and nutritional benefits of plain cow’s milk.
In addition, researchers are working on lab-made mozzarella that melts perfectly on pizza, as well as cheese and other ice cream.
Carbon emissions are a big concern when it comes to commercial aviation, but there is a potential solution and it has received a lot of funding.
A UK project worth 15 million pounds has announced plans to build an aircraft with hydrogen propulsion. The project is known as Fly Zero and is managed by the Institute of Aerospace Technology in collaboration with the UK Government.
This project emerged with the concept of a medium-sized aircraft equipped with liquid hydrogen. It can fly around 279 passengers around the world non-stop.
If this technology could be applied, it could mean non-stop flights between London and the Americas West or London to New Zealand with one stop.
In Star Trek, where many of our ideas about future technology originate, people can go to medical facilities and perform digital full-body scans for signs of illness and injury. This in real life, say the creators of Q Bio, will improve health outcomes and at the same time ease the burden on doctors.
The American company has created a scanner that will measure hundreds of biological markers in about an hour, from hormone levels to fat deposits in your liver to markers of inflammation or some cancers. He intends to use this data to create a 3D digital avatar of a patient’s body – known as a digital twin – which can be tracked over time and updated with each new scan.
Q Bio CEO Jeff Kaditz hopes this will usher in a new era of prevention, personalized medicine, where the vast amounts of data collected will not only help doctors identify priorities that need to be addressed by patients early on, but also develop better ways to diagnose disease. . .
After a drastic name change, the company that used to be known as Facebook, became Meta. This means Zuckerberg and his big team are moving on metaworld – embodies the Internet, mostly accessed via virtual and augmented reality.
As part of this step, we’ll begin to see that Meta devotes more time to tools to access these new worlds – mostly in VR. Announced back in 2021, Meta is developing a new headset called “Project Cambria”.
Unlike previous brand VR businesses like the Oculus Quest 2, this won’t be a device for the average consumer.
Cambria is reportedly focusing on better eye and face tracking (to improve the accuracy of your avatar and your movements in-game), higher resolutions, increased field of view, and even trying to make the headset much smaller.
Between Meta, Google, Sony and many other big tech companies, VR is now getting a lot of funding and the next few years will see a dramatic increase.
Due to the process of photosynthesis, trees remain one of the best ways to reduce CO2 levels in the atmosphere. However, new technologies can play the same role as trees, absorbing carbon dioxide at higher rates and taking up less land.
This technology is known as Direct Air Intake (DAC). This involves extracting carbon dioxide from the air and storing CO 2 in geological caverns deep underground, or using it in combination with hydrogen to produce synthetic fuels.
Although this technology has great potential, it has many challenges. Direct air intake devices are now available and working, but current models require a large amount of energy to operate. If energy levels can be reduced in the future, DACs could be one of the best technological advances for the environment of the future.
Sustainable living is a priority for people responding to the realities of the climate crisis, but what about environmentally friendly deaths? Death is usually a carbon-rich process, the final stamp of our environmental footprint. On average, for example, cremation emits 400 kg of carbon dioxide. So what is more environmentally friendly?
In the US state of Washington, you can compost instead. The bodies were laid in a room with bark, earth, straw and other compounds that promote natural decomposition. Within 30 days your body turns into soil that can be returned to the garden or forest. The company Recompose, which is behind the process, claims to use one-eighth of the carbon dioxide from cremation.
Alternative technology using mushrooms. In 2019, the late actor Luke Perry was buried in a custom-made “mushroom costume” developed by a startup called Coeio. The company claims that the suits are made of mold and other microorganisms that promote decay and neutralize toxins that are sold when the normal body breaks down.
Most alternative ways of disposing of our bodies after death are not based on new technology; they are just waiting for public acceptance to catch up. Another example is alkaline hydrolysis, which involves breaking down the body into its chemical components for six hours in an airtight chamber. It is legal in a number of US states and uses fewer emissions than more traditional methods.
The bionic eye has been a mainstay of science fiction for decades, but now real-world research is starting to catch up to the farsighted narrator. A number of technologies are on the market that restore vision to people with various visual impairments.
In January 2021, Israeli surgeons implanted the world’s first artificial cornea in a 78-year-old bilaterally blind man. When the bandage is removed, the patient can immediately read and recognize family members. The implant also naturally blends into human tissue without removing it from the recipient’s body.
Similarly, in 2020, Belgian scientists have developed an artificial iris attached to a smart contact lens that corrects a number of visual impairments. And scientists are even working on a wireless brain implant that completely ignores the eye.
Researchers from Montache University in Australia are working to test a system in which users wear glasses with a camera. It transmits data directly to an implant that is on the surface of the brain and provides the user with a basic sense of vision.
Our crowded cities are in dire need of rest, and help may come from the air rather than from the road. With City Airport, funded by the UK Government.
It’s being built in Coventry. The hub will serve as a pilot scheme and hopefully a testament to the company concept behind it. The idea, running off-grid from hydrogen generators, is to eliminate the need for as many vans and cars on our roads as possible, replacing them with a pure alternative in the form of a new type of small plane with an improved design. Huyundai and Airbus, among others.
Infrastructure will be important. Organizations such as the Civil Aviation Authority are considering creating air corridors that could link the city center with local airports or distribution centers.
Scientists have found a way to store energy in red bricks, which are used to build houses.
Researchers led by the University of Washington at St. Louis, Missouri, has developed a method that can convert inexpensive and widely available building materials into “smart bricks” that can store energy like batteries.
Although research is still in the process of confirming the concept, scientists claim that these brick walls “can store large amounts of energy” and can “charge hundreds of thousands of times in an hour.”
Researchers have developed a method for turning red bricks into a type of energy storage called a supercapacitor.
This involves applying a conductive coating, known as Pedo, to a sample of bricks, which then seeps through the porous structure of the burned bricks, turning them into “energy-saving electrodes”.
Researchers say iron oxide, which is the red pigment in bricks, aids the process.
Engineers from the University of Glasgow have developed a new type of flexible supercapacitor that stores energy, replaces the electrolyte found in conventional batteries with sweat.
It can be fully charged in just 20 microliters of liquid and is strong enough to withstand the 4,000 cycles of twists and turns that can occur during use.
This tool works by coating a polyester cellulose cloth with a thin layer of polymer that acts as a supercapacitor electrode.
As the fabric absorbs the sweat of its owner, the positive and negative ions in the sweat interact with the polymer surface, creating an electrochemical reaction that generates energy.
“Conventional batteries are cheaper and richer than ever, but are often made using unstable materials that are harmful to the environment,” says Professor Ravinder Dahia , head of the flexible electronics and sound technology group (Best), based at the James Watt School of Engineering at the University of Glasgow.
“This makes them difficult for safe disposal and is potentially dangerous in wearables where a faulty battery can spill toxic liquid onto the skin.
“For the first time, we were able to show that human sweat provides a real opportunity to completely eliminate this toxic material with excellent charge and discharge performance.
Scientists have developed what they call live concrete using sand, gel, and bacteria.
Researchers say that this building material has a load-bearing function, is able to cure and more environmentally friendly than concrete – which is the second most consumed material on Earth after water.
The team from the University of Colorado Boulder believe their work is paving the way for future building structures that can “heal their own cracks, suck harmful toxins out of the air or even glow on command.”
tiny hybrid robots created using stem cells from frog embryos could one day be used to swim around the human body in areas that require drugs, or collect microplastics in the oceans.
“This is a new living machine,” said Joshua Bongard, computer scientist and Joshua Bongard</a > A roboticist from the University of Vermont who co-developed millimeter bots known as xenobots.
“They are not traditional robots and not a known animal species. This is an artifact of a new class: programmable living organisms.
It seems we can’t live without the Internet (how else do you read sciencefocus.com?), but still only about half the world’s population is connected. There are many reasons for this, including economic and social, but for some people the internet is not available because there is no connection.
Google is slowly trying to solve the problem by using helium balloons to transfer internet to hard-to-reach areas, while Facebook has dropped plans to do the same with drones, meaning companies like Hiber are stealing the march. They’ve taken a different approach by launching into low Earth orbit their own network of shoe-sized microsatellites that wake up a modem connected to your computer or device as it passes by and transmits your data.
Their satellites orbit Earth 16 times a day and are already used by organizations such as The British Antarctic Survey to provide Internet access in the most extreme parts of our planet.
One day the forest fires were extinguished with the help of a drone that would direct a loud sound at the trees below. Since sound is made up of pressure waves, it can be used to destroy the air around a fire, essentially stopping the oxygen supply to the fuel. At the right frequency, fires simply go out, as researchers at George Mason University in Virginia recently demonstrated with their sonic fire extinguishers. Apparently, the bass frequencies work best.
Fast charging of electric vehicles is considered key to their use, so motorists can stop at a service station and fully charge their car for the time it takes to drink coffee and use the toilet – nothing more than a regular break.
But fast charging lithium-ion batteries can lead to battery degradation, say researchers from the University of Pennsylvania in the United States. This is because the flow of lithium particles, known as ions, from one electrode to another to charge devices and conserve ready-to-use energy does not occur smoothly with fast charging at lower temperatures.
However, they have now discovered that if a battery could heat up to 60°C in just 10 minutes and then cool rapidly back to ambient temperature, lithium spikes would not form and heat damage could be avoided.
Their battery design is self-heating using a thin nickel foil that creates an electrical circuit that heats up in less than 30 seconds to heat the inside of the battery. Quick cooling, which will be required after charging the battery, will be carried out using a cooling system built into the car.
Their study, published in the journal Joule, found that they could fully charge an electric car in 10 minutes.
Scientists have found a way to attach artificial neurons to silicon chips by mimicking the neurons in our nervous system and copying their electrical properties.
“Until now, neurons were like black boxes, but we were able to open the black box and look inside,” said Professor Alain Nogaret of the University of Bath, who led the project.
“Our work is paradigm-shifting as it provides a reliable method for reproducing the electrical properties of real neurons in detail.
“But it’s wider because our neurons only need 140 nanoenergy. This is a millionth of the power of the microprocessor used by other attempts to make synthetic neurons.
The researchers hope their work can be used in medical implants to treat diseases such as heart failure and Alzheimer’s because they require very little energy.
The United Nations estimates that by 2050 the world will have two billion more people, which will create 70 percent of the demand for food. By then, 80 percent of us will live in cities, and most of the food we eat in urban areas is imported. Thus, farms moored in inland seas or lakes near cities will inevitably cut food distances.
But how will they work? Designed by architect Javier Ponce of Forward Thinking Architecture, the building is a 24-foot-tall three-story structure with solar panels on top for power. The intermediate level grows a variety of vegetables in an area of 51,000 m 2, using not nutrients but nutrients in liquids. These nutrients and plant substances enter the lower layers to feed fish growing indoors.
One smart floating farm measuring 350 x 200 m will produce about 8.1 tons of vegetables and 1.7 tons of fish per year. Units are designed to be connected to each other, which is convenient because we need a lot: Dubai, for example, imports 11,000 tons of fruit and vegetables every day.