Hypersonic missiles are in military use 2025-2030
When launched, cruise missiles have typically reached 500-600 mph (800-965 km/h). However, a new generation of air-breathing supersonic combustion ramjet (scramjet) engines is now emerging on the battlefield after many years of testing and development. These are capable of exceeding Mach 5, or about 3,840 mph (6,150 km/h), making them hypersonic.
As well as enhancing the responsiveness of a warfighter, the survivability of these missiles as they fly over enemy territory is greatly improved, since they are difficult (if not impossible) to hit at such a high speed.
Now that military use of scramjets has been perfected, commercial use will soon follow. In the 2030s, the first hypersonic airliners begin to appear, capable of travelling around the globe in under four hours.
Country Think to Do:-
2.Human Brain simulations are Becoming possible
The exponential growth of computer processing power has made it possible to form accurate models of every part of the human brain. Between 2000 and 2025, there is a millionfold increase in computational power, together with vastly improved scanning resolution and bandwidth.
Until recently, only separate regions of the brain had been modelled in any detail – but scientists are now able to combine them into a complete, real-time simulation. Like the Human Genome Project, there were many in the scientific community who doubted the brain could be mapped so quickly. Once again, they failed to account for the exponential (rather than linear) growth of information technology.
3. 3D-printed human organs
Additive manufacturing, also known as 3D printing, was first developed in the mid-1980s. Initially used for industrial applications such as rapid prototyping, it fell dramatically in cost during the 2010s and became available to a much wider audience.
Arguably the most transformative breakthroughs were occurring in health and medicine. Customised, 3D-printed body parts were saving peoples' lives and included artificial jaw bones,bioresorbable splints for breathing and replacement skull parts, among many other uses. Non-critical applications included dental implants and exoskeletons to assist with mobility and joint movement
Even greater advances were taking place, however. 3D printing was no longer limited to inorganic materials like polymers or metals. It was being adapted to construct living, biological systems. Layer after layer of cells, dispensed from printer heads, could be placed exactly where needed with precision down to micrometre scales. Initially demonstrated for simple components like blood vessels and tissues more sophisticated versions later emerged in combination with scaffolds to hold larger structures in place. Eventually, the first complete organs were developed with sufficient nutrients, oxygen and growth vectors to survive as fully-functioning replacements in mouse models.
By 2025 – after testing on animals – customised 3D-printing of major human organs is becoming feasible for the first time. Although yet to be fully perfected (as certain types of organs remain too complex), this is nevertheless a major boost for life extension efforts. In the coming decades, more and more of the 78 organs in the human body will become printable.
When launched, cruise missiles have typically reached 500-600 mph (800-965 km/h). However, a new generation of air-breathing supersonic combustion ramjet (scramjet) engines is now emerging on the battlefield after many years of testing and development. These are capable of exceeding Mach 5, or about 3,840 mph (6,150 km/h), making them hypersonic.
As well as enhancing the responsiveness of a warfighter, the survivability of these missiles as they fly over enemy territory is greatly improved, since they are difficult (if not impossible) to hit at such a high speed.
Now that military use of scramjets has been perfected, commercial use will soon follow. In the 2030s, the first hypersonic airliners begin to appear, capable of travelling around the globe in under four hours.
Country Think to Do:-
- U.S
- RUSSIA
- INDIA
- CHINA
2.Human Brain simulations are Becoming possible
The exponential growth of computer processing power has made it possible to form accurate models of every part of the human brain. Between 2000 and 2025, there is a millionfold increase in computational power, together with vastly improved scanning resolution and bandwidth.
Until recently, only separate regions of the brain had been modelled in any detail – but scientists are now able to combine them into a complete, real-time simulation. Like the Human Genome Project, there were many in the scientific community who doubted the brain could be mapped so quickly. Once again, they failed to account for the exponential (rather than linear) growth of information technology.
3. 3D-printed human organs
Additive manufacturing, also known as 3D printing, was first developed in the mid-1980s. Initially used for industrial applications such as rapid prototyping, it fell dramatically in cost during the 2010s and became available to a much wider audience.
Arguably the most transformative breakthroughs were occurring in health and medicine. Customised, 3D-printed body parts were saving peoples' lives and included artificial jaw bones,bioresorbable splints for breathing and replacement skull parts, among many other uses. Non-critical applications included dental implants and exoskeletons to assist with mobility and joint movement
Even greater advances were taking place, however. 3D printing was no longer limited to inorganic materials like polymers or metals. It was being adapted to construct living, biological systems. Layer after layer of cells, dispensed from printer heads, could be placed exactly where needed with precision down to micrometre scales. Initially demonstrated for simple components like blood vessels and tissues more sophisticated versions later emerged in combination with scaffolds to hold larger structures in place. Eventually, the first complete organs were developed with sufficient nutrients, oxygen and growth vectors to survive as fully-functioning replacements in mouse models.
By 2025 – after testing on animals – customised 3D-printing of major human organs is becoming feasible for the first time. Although yet to be fully perfected (as certain types of organs remain too complex), this is nevertheless a major boost for life extension efforts. In the coming decades, more and more of the 78 organs in the human body will become printable.
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| 3D Printing Organs 2025 |
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