[Tee tiong huat]

Scientists achieve teleportation between quantum computers for the first time ever me The promise of quantum computing come with a hitch: the more qubits you load into a single machine, the harder they are to keep in line. Scientists have tried shielding, error correction, even stacking qubits on top of one another, yet stability keeps slipping through their fingers.

A fresh demonstration now points to a different strategy – spreading the workload across several small processors and letting quantum teleportation knit them together in real time. Teleportation in this context doesn’t fling matter through space. Instead, it transfers a qubit’s delicate “both-at-once” state to a partner qubit some distance away, using entanglement and a quick burst of old-fashioned binary data. Until recently, practical attempts rarely pushed beyond proof-of-concept.. Now researchers have used the teleportation trick to forge a working logic gate between two separate quantum chips sitting about six feet apart, hinting at a future where clusters of modest processors act as one mighty computer.

Quantum teleportation and qubits
A qubit is valuable because it can be zero and one at the same moment, yet that superposition collapses if the qubit feels a nudge from the outside world.. By teleporting a qubit’s identity rather than physically hauling the particle around, engineers sidestep much of that fragility. The receiving end simply reshapes its own qubit to mirror the original and carries on with the calculation.

The latest experiment used a pair of “network” qubits – atoms optimized for sending and receiving optical signals – and a pair of “circuit” qubits dedicated to crunching data. Teleportation bridged the network qubits first; the entangled link then let the circuit qubits act as though they shared the same chip.

[Tee tiong huat]

Scientists achieve teleportation between quantum computers for the first time ever me The promise of quantum computing come with a hitch: the more qubits you load into a single machine, the harder they are to keep in line. Scientists have tried shielding, error correction, even stacking qubits on top of one another, yet stability keeps slipping through their fingers.

A fresh demonstration now points to a different strategy – spreading the workload across several small processors and letting quantum teleportation knit them together in real time. Teleportation in this context doesn’t fling matter through space. Instead, it transfers a qubit’s delicate “both-at-once” state to a partner qubit some distance away, using entanglement and a quick burst of old-fashioned binary data. Until recently, practical attempts rarely pushed beyond proof-of-concept.. Now researchers have used the teleportation trick to forge a working logic gate between two separate quantum chips sitting about six feet apart, hinting at a future where clusters of modest processors act as one mighty computer.

Quantum teleportation and qubits
A qubit is valuable because it can be zero and one at the same moment, yet that superposition collapses if the qubit feels a nudge from the outside world.. By teleporting a qubit’s identity rather than physically hauling the particle around, engineers sidestep much of that fragility. The receiving end simply reshapes its own qubit to mirror the original and carries on with the calculation.

The latest experiment used a pair of “network” qubits – atoms optimized for sending and receiving optical signals – and a pair of “circuit” qubits dedicated to crunching data. Teleportation bridged the network qubits first; the entangled link then let the circuit qubits act as though they shared the same chip.

That separation may sound modest, yet even a six-foot gap lets designers slide in upgrades, repairs, or entirely new hardware without cracking open a refrigerated chamber the size of a wardrobe. Flexibility beats brute-force scaling. Early roadmaps for quantum hardware leaned on cramming thousands of qubits onto a single platform. The physics community quickly learned that error rates ballooned as qubits multiplied, forcing ever-heavier error-correction overhead. Distributing processors flips that script. Each module can stay small enough for tight control & teleportation stitches operations together on demand.

Oxford quantum teleportation experiment. Only after the teleportation link was humming did the wider world learn who pulled it off: a team at Oxford University led by physicist Dougal Main.
“Previous demonstrations of quantum teleportation have focused on transferring quantum states between physically separated systems,” Dougal Main explains. “In our study, we use quantum teleportation to create interactions between these distant systems.”

The team’s setup entangled two ytterbium ions, fired off the required classical bits, and recreated a spin state on the far side with an 86 percent match.
That fidelity crossed the threshold for a basic logic gate, so the researchers ran a compact version of Grover’s search algorithm. Distributed gate delivered correct answer 71% of the time  respectable for early hardware crucially, limited more by local imperfections than by the teleportation itself.

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That separation may sound modest, yet even a six-foot gap lets designers slide in upgrades, repairs, or entirely new hardware without cracking open a refrigerated chamber the size of a wardrobe. Flexibility beats brute-force scaling. Early roadmaps for quantum hardware leaned on cramming thousands of qubits onto a single platform. The physics community quickly learned that error rates ballooned as qubits multiplied, forcing ever-heavier error-correction overhard
& Distributing processors flips that script. Each module can stay small enough for tight control & teleportation stitches operations together on demand. Oxford quantum teleportation experiment. Only after the teleportation link was humming did the wider world learn who pulled it off: a team at Oxford University led by physicist Dougal Main. “Previous demonstrations of quantum teleportation have focused on transferring quantum states between physically separated systems,” Dougal Main explains. “In our study, we use quantum teleportation to create interactions between these distant systems.” The team’s setup entangled two ytterbium ions, fired off the required classical bits, and recreated a spin state on the far side with an 86 percent match. That fidelity crossed the threshold for a basic logic gate, so the researchers ran a compact version of Grover’s search algorithm. Distributed gate delivered correct answer 71% of the time  respectable for early hardware crucially, limited more by local imperfections than by the teleportation itself.

Tests that prove the link works
The group didn’t stop at one gate. They executed SWAP and iSWAP operations – building blocks for more elaborate circuits – without moving the ions from their respective traps. Each success chipped away at the notion that distance inherently drags down performance.

“By interconnecting the modules using photonic links, our system gains valuable flexibility, allowing modules to be upgraded or swapped out without disrupting the entire architecture,” says Main. Flexibility, in this setting, is not a luxury feature; it is the difference between a brittle science project and a sustainable computing platform.
The group didn’t stop at one gate. They executed SWAP and iSWAP operations – building blocks for more elaborate circuits – without moving the ions from their respective traps. Each success chipped away at the notion that distance inherently drags down performance.

“By interconnecting the modules using photonic links, our system gains valuable flexibility, allowing modules to be upgraded or swapped out without disrupting the entire architecture,” says Main. Flexibility, in this setting, is not a luxury feature; it is the difference between a brittle science project and a sustainable computing platform.

[Tee tiong huat]

Scientists achieve teleportation between quantum computers for the first time ever me The promise of quantum computing come with a hitch: the more qubits you load into a single machine, the harder they are to keep in line. Scientists have tried shielding, error correction, even stacking qubits on top of one another, yet stability keeps slipping through their fingers.

A fresh demonstration now points to a different strategy – spreading the workload across several small processors and letting quantum teleportation knit them together in real time. Teleportation in this context doesn’t fling matter through space. Instead, it transfers a qubit’s delicate “both-at-once” state to a partner qubit some distance away, using entanglement and a quick burst of old-fashioned binary data. Until recently, practical attempts rarely pushed beyond proof-of-concept.. Now researchers have used the teleportation trick to forge a working logic gate between two separate quantum chips sitting about six feet apart, hinting at a future where clusters of modest processors act as one mighty computer.

Quantum teleportation and qubits
A qubit is valuable because it can be zero and one at the same moment, yet that superposition collapses if the qubit feels a nudge from the outside world.. By teleporting a qubit’s identity rather than physically hauling the particle around, engineers sidestep much of that fragility. The receiving end simply reshapes its own qubit to mirror the original and carries on with the calculation.

The latest experiment used a pair of “network” qubits – atoms optimized for sending and receiving optical signals – and a pair of “circuit” qubits dedicated to crunching data. Teleportation bridged the network qubits first; the entangled link then let the circuit qubits act as though they shared the same chip.

1. Quantum entanglement and qubits are fundamental concepts in quantum computing. Qubits, the basic unit of quantum information, can exist in a superposition of 0 & 1, unlike classical bits which are either 0 or 1. Quantum entanglement is a phenomenon where two or more qubits become linked, regardless of the distance separating them, in a way that their fates are intertwined. If you measure the state of one entangled qubit, you instantly know the state of the other(s), even if they
   

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Michio Kaku SHOCKED: Proxima B Just Confirmed Alien Life|. Renowned theoretical physicist Michio Kaku is in shock after NASA and the James Webb Space Telescope reportedly confirmed the most direct signs of alien life on Proxima B — closest to Earth-like planet 4 light year to our solar system. From mysterious biosignatures to unexplainable energy patterns & light anomalies, the evidence points toward one undeniable conclusion: we may not alone. Scientists around the world are calling this the beginning of a new era — one where first contact is no longer science fiction...but imminent reality.

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Michio Kaku SHOCKED: Proxima B Just Confirmed Alien Life|. Renowned theoretical physicist Michio Kaku is in shock after NASA and the James Webb Space Telescope reportedly confirmed the most direct signs of alien life on Proxima B — closest to Earth-like planet 4 light year to our solar system. From mysterious biosignatures to unexplainable energy patterns & light anomalies, the evidence points toward one undeniable conclusion: we may not alone. Scientists around the world are calling this the beginning of a new era — one where first contact is no longer science fiction...but imminent reality.

https://youtu.be/SYTw7C8J2vU?si=0CXGEdD1Px4mH-I_

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James Webb Space Telescope has done it again—this time, by unveiling the breathtaking and almost unimaginable scale of our universe. In this awe-inspiring video, we break down the latest high-resolution images and data that show galaxies stretching farther than ever seen before, cosmic structures forming just after the Big Bang, and a universe far more vast and complex than we ever imagined. From ancient light traveling billions of years to mind-bending discoveries that challenge our place in the cosmos, this is a journey through space you won’t forget. Witness the true scale of the universe—revealed like never before.
https://youtu.be/REPGJcCuDQ8?si=W6ndAaoh8xfWeUyz

[Tee tiong huat]

Scientists achieve teleportation between quantum computers for the first time ever me The promise of quantum computing come with a hitch: the more qubits you load into a single machine, the harder they are to keep in line. Scientists have tried shielding, error correction, even stacking qubits on top of one another, yet stability keeps slipping through their fingers.

A fresh demonstration now points to a different strategy – spreading the workload across several small processors and letting quantum teleportation knit them together in real time. Teleportation in this context doesn’t fling matter through space. Instead, it transfers a qubit’s delicate “both-at-once” state to a partner qubit some distance away, using entanglement and a quick burst of old-fashioned binary data. Until recently, practical attempts rarely pushed beyond proof-of-concept.. Now researchers have used the teleportation trick to forge a working logic gate between two separate quantum chips sitting about six feet apart, hinting at a future where clusters of modest processors act as one mighty computer.

Quantum teleportation and qubits
A qubit is valuable because it can be zero and one at the same moment, yet that superposition collapses if the qubit feels a nudge from the outside world.. By teleporting a qubit’s identity rather than physically hauling the particle around, engineers sidestep much of that fragility. The receiving end simply reshapes its own qubit to mirror the original and carries on with the calculation.

The latest experiment used a pair of “network” qubits – atoms optimized for sending and receiving optical signals – and a pair of “circuit” qubits dedicated to crunching data. Teleportation bridged the network qubits first; the entangled link then let the circuit qubits act as though they shared the same chip.

Scientists have achieved a significant breakthrough by successfully teleporting information between two quantum computers. This involved transferring quantum state of a qubit (basic unit of quantum information) between separate quantum processors with 86% accuracy. The experiment, conducted by researchers at Oxford University, demonstrates  feasibility of distributed quantum computing could pave way for more powerful quantum computers.

[Tee tiong huat]

Scientists have achieved a significant breakthrough by successfully teleporting information between two quantum computers. This involved transferring quantum state of a qubit (basic unit of quantum information) between separate quantum processors with 86% accuracy. The experiment, conducted by researchers at Oxford University, demonstrates  feasibility of distributed quantum computing could pave way for more powerful quantum computers.

How can a cable that transmits our internet teleport messages?.


This idea of using fiber optic cables to teleport messages is not new, but only recently has a study put this idea into practice. 

We are talking about the experiment led by Northwestern University in the U.S, which finally proved that quantum data and traditional internet data can coexist in the same optical fiber.

Ahh!. How this be possible?.

Well, here we'll have to get into some technical terms: to begin with, we must remember that quantum communication 
(does not use electrical impulses or conventional waves), it depends on individual photons, which are carriers of very sensitive quantum states, can lost when exposed to interference.* And that is where problem lies: here fibers we use today are full of intense signals from the traditional internet, causing a type of “  Optical Pollution” tends to destroy any quantum data in its path. Ok, then how did they make teleportation possible?...right?.

[Tee tiong huat]

How can a cable that transmits our internet teleport messages?.

This idea of using fiber optic cables to teleport messages is not new, but only recently has a study put this idea into practice. 

We are talking about the experiment led by Northwestern University in the U.S, which finally proved that quantum data and traditional internet data can coexist in the same optical fiber.

Ahh!. How this be possible?.

Well, here we'll have to get into some technical terms: to begin with, we must remember that quantum communication 
(does not use electrical impulses or conventional waves), it depends on individual photons, which are carriers of very sensitive quantum states, can lost when exposed to interference.* And that is where problem lies: here fibers we use today are full of intense signals from the traditional internet, causing a type of “  Optical Pollution” tends to destroy any quantum data in its path. Ok, then how did they make teleportation possible?...right?.

Experts achieve teleportation — We can send information to the far universe https://share.google/5ckDNohgNVGH5ssrX

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Ahh!. How this be possible?.

Well, to get around such situation, the researchers separated the signals by wavelength. How is this is possible?.

that is the job for Science researchers to work on the quantum photons to go through a "less noisy” band of spectrum, while the internet signals used the C band, (the most common). 

The result you or maybe some probably already know: they achieved a stable quantum communication channel, which can allow us to send info everywhere.

Can us teleport anything we want?.

So to us,...does this mean in addition to sending messages to the universe, this discovery will allow us to teleport ourselves around (as some German scientists did in this example)?.

Not quite yet … however, this new development is very similar to dream of  
teleporting oneself.
When thinking about technological aspect, of course....lehh.

After all, they created a practically instantaneous communication channel, and this redefines the limits of what, we understand when we think about sending information over great distances.

[Tee tiong huat]

Ahh!. How this be possible?.

Well, to get around such situation, the researchers separated the signals by wavelength. How is this is possible?.

that is the job for Science researchers to work on the quantum photons to go through a "less noisy” band of spectrum, while the internet signals used the C band, (the most common). 

The result you or maybe some probably already know: they achieved a stable quantum communication channel, which can allow us to send info everywhere.

Can us teleport anything we want?.

So to us,...does this mean in addition to sending messages to the universe, this discovery will allow us to teleport ourselves around (as some German scientists did in this example)?.

Not quite yet … however, this new development is very similar to dream of  
teleporting oneself.
When thinking about technological aspect, of course....lehh.

After all, they created a practically instantaneous communication channel, and this redefines the limits of what, we understand when we think about sending information over great distances.

https://www.ecoticias.com/en/experts-ach...ion/15993/

[Tee tiong huat]

Ahh!. How this be possible?.

Well, to get around such situation, the researchers separated the signals by wavelength. How is this is possible?.

that is the job for Science researchers to work on the quantum photons to go through a "less noisy” band of spectrum, while the internet signals used the C band, (the most common). 

The result you or maybe some probably already know: they achieved a stable quantum communication channel, which can allow us to send info everywhere.

Can us teleport anything we want?.

So to us,...does this mean in addition to sending messages to the universe, this discovery will allow us to teleport ourselves around (as some German scientists did in this example)?.

Not quite yet … however, this new development is very similar to dream of  
teleporting oneself.
When thinking about technological aspect, of course....lehh.

After all, they created a practically instantaneous communication channel, and this redefines the limits of what, we understand when we think about sending information over great distances.

Chinese Electric Cars in Israel Found to Be Transmitting Data to China.

Israeli Ministry of Defense has officially suspended the supply of Chinese electric vehicles from BYD to IDF officers due to concerns over data collection via embedded communication systems and sensors. Ynetnews reported on this. The
ban came after numerous warnings from cybersecurity experts, who emphasized that Chinese vehicles could be used as tools for espionage. This is only one eg:

Earlier, the Israeli Ministry of Defense had already received over 600 Chinese vehicles, including the MG ZS EV and Chery Tiggo 8 models, which were actively used as official transport for officers, even near the Ministry of Defense headquarters in Tel Aviv.

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Chinese Electric Cars in Israel Found to Be Transmitting Data to China.

Israeli Ministry of Defense has officially suspended the supply of Chinese electric vehicles from BYD to IDF officers due to concerns over data collection via embedded communication systems and sensors. Ynetnews reported on this. The ban came after numerous warnings from cybersecurity experts, who emphasized that Chinese vehicles could be used as tools for espionage. This is only one eg:

Earlier, the Israeli Ministry of Defense had already received over 600 Chinese vehicles, including the MG ZS EV and Chery Tiggo 8 models, which were actively used as official transport for officers, even near the Ministry of Defense headquarters in Tel Aviv.

https://militarnyi.com/en/news/chinese-e...-to-china/

[Tee tiong huat]

Ahh!. How this be possible?.

Well, to get around such situation, the researchers separated the signals by wavelength. How is this is possible?.

that is the job for Science researchers to work on the quantum photons to go through a "less noisy” band of spectrum, while the internet signals used the C band, (the most common). 

The result you or maybe some probably already know: they achieved a stable quantum communication channel, which can allow us to send info everywhere.

Can us teleport anything we want?.

So to us,...does this mean in addition to sending messages to the universe, this discovery will allow us to teleport ourselves around (as some German scientists did in this example)?.

Not quite yet … however, this new development is very similar to dream of  
teleporting oneself.
When thinking about technological aspect, of course....lehh.

After all, they created a practically instantaneous communication channel, and this redefines the limits of what, we understand when we think about sending information over great distances.

Nothing is safe with stupid such kind of thing like...  

Like instantaneous communication channel.

[Tee tiong huat]

Scientists achieve teleportation between quantum computers for the first time ever me The promise of quantum computing come with a hitch: the more qubits you load into a single machine, the harder they are to keep in line. Scientists have tried shielding, error correction, even stacking qubits on top of one another, yet stability keeps slipping through their fingers.

A fresh demonstration now points to a different strategy – spreading the workload across several small processors and letting quantum teleportation knit them together in real time. Teleportation in this context doesn’t fling matter through space. Instead, it transfers a qubit’s delicate “both-at-once” state to a partner qubit some distance away, using entanglement and a quick burst of old-fashioned binary data. Until recently, practical attempts rarely pushed beyond proof-of-concept.. Now researchers have used the teleportation trick to forge a working logic gate between two separate quantum chips sitting about six feet apart, hinting at a future where clusters of modest processors act as one mighty computer.

Quantum teleportation and qubits
A qubit is valuable because it can be zero and one at the same moment, yet that superposition collapses if the qubit feels a nudge from the outside world.. By teleporting a qubit’s identity rather than physically hauling the particle around, engineers sidestep much of that fragility. The receiving end simply reshapes its own qubit to mirror the original and carries on with the calculation.

The latest experiment used a pair of “network” qubits – atoms optimized for sending and receiving optical signals – and a pair of “circuit” qubits dedicated to crunching data. Teleportation bridged the network qubits first; the entangled link then let the circuit qubits act as though they shared the same chip.

Where our!. Potential Impact on above 
Teleportation is Progressive very well.

Here On Saturn?: Astronomers Appeal For Help???. As Video Appears To Show Object Hitting The Gas Giant. On July 5, between 9:00 and 9:15 UTC, something appears to have hit Saturn. If verified, it will be the first ever to be caught on camera...

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Here another detection or real problem or isit some problem on July 5, 2025.
https://m.economictimes.com/news/new-upd...877309.cms

Magnitude 6.0, Tue Jul 8 2025 12:53 AM. Earthquake...ok.

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Magnitude 6.0, Tue Jul 8 2025 12:53 AM. Earthquake...ok.

Not in Japan, but Far, Far South

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https://youtu.be/1SqAYSK_0hE?si=twA-BWzNtYNqZgLG

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What followed was one of the most extraordinary and little-known close encounters in Cold War history. Based on the investigation by Canadian UFO researcher, Chris Styles, and his book: "Sweep Clear 5", we delve into the chilling details of what two divers claim they saw resting on the seabed: two flying saucers, strange humanoid beings, and a top-secret naval response that remained buried for over 60 years.

In October 1960, during a routine NATO minesweeping exercise off the coast of Shelburne, Nova Scotia, a Canadian warship HMCS Cape Scott suddenly halted operations & assumed DEFCON 1, rhe highest state of military readiness. Mysterious events, an strange.

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What followed was one of the most extraordinary and little-known close encounters in Cold War history. Based on the investigation by Canadian UFO researcher, Chris Styles, and his book: "Sweep Clear 5", we delve into the chilling details of what two divers claim they saw resting on the seabed: 2 flying saucers, strange humanoid beings, a top-secret naval response remained buried for over 60 years. In October 1960, during a routine NATO minesweeping exercise off coast of Shelburne, Nova Scotia, a Canadian warship HMCS Cape Scott suddenly halted operation assumed DEFCON 1, the highest state of military readiness. Mysterious & events very strange.

https://youtu.be/QNUqFAFGTHc?si=5aztaA71I_eYn19O

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On July 1st, 2025, astronomers detected a faint moving dot using ATLAS telescopes in Hawai‘i & South Africa. Its motion was unusual, its speed extreme, & its path clearly interstellar. It was soon confirmed as only the third known object to enter our solar system from beyond. Its official name is 3I/ATLAS.

Early telescope data suggests 3I/ATLAS maybe an active comet. A faint coma appears to be forming around it, possibly
result of volatile gases being released as the object warms. This behavior already places it closer to comet 2I/Borisov, which also showed familiar signs of activity during its visit in 2019.

But this is where things get strange. Because if ATLAS and Borisov both behave like normal comets, why did ʻOumuamua, first known interstellar object, behave so differently? ʻOumuamua had no visible coma, no tail, no thermal emission. & yet it accelerated on its way out, as if something invisible had nudged it. The mystery only deepens in comparison.

To uncover truth, scientists are drawing up plans for a mission called Project Lyra. If launched, could one day chase ʻOumuamua down & examine it up close, decades from now, then, comparisons like these are our only clues. And now, the Vera C. Rubin Observatory is finally online. Its first light image was released in July 2025, marking the beginning of full science operations. Over the next decade, Rubin will scan the sky every few nights, giving us our best shot yet at spotting the next interstellar visitor before it slips away

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On July 1st, 2025, astronomers detected a faint moving dot using ATLAS telescopes in Hawai‘i & South Africa. Its motion was unusual, its speed extreme, & its path clearly interstellar. It was soon confirmed as only the third known object to enter our solar system from beyond. Its official name is 3I/ATLAS. Early telescope data suggests 3I/ATLAS maybe an active comet. A faint coma appears to be forming around it, possibly result of volatile gases being released as the object warms. This behavior already places it closer to comet 2I/Borisov, which also showed familiar signs of activity during its visit in 2019.

But this is where things get strange. Because if ATLAS and Borisov both behave like normal comets, why did ʻOumuamua, first known interstellar object, behave so differently? ʻOumuamua had no visible coma, no tail, no thermal emission. & yet it accelerated on its way out, as if something invisible had nudged it. The mystery only deepens in comparison.

To uncover truth, scientists are drawing up plans for a mission called Project Lyra. If launched, could one day chase ʻOumuamua down & examine it up close, decades from now, then, comparisons like these are our only clues. And now, the Vera C. Rubin Observatory is finally online. Its first light image was released in July 2025, marking the beginning of full science operations. Over the next decade, Rubin will scan the sky every few nights, giving us our best shot yet at spotting the next interstellar visitor before it slips away

https://youtu.be/kkqVQPbMA3o?si=ZpvRN5o2Uvd3-iYr

[Tee tiong huat]

Astronomers discover giant alien planet 35 times more massive than Earth hiding in a known star system. "It remains possible other unseen planets in the system &  challenge is finding them!".
Scientists have detected a hidden alien planet by examining the orbits of the known worlds in the star system, known as Kepler-139. The newfound exoplanet, called Kepler-139f, is a gigantic world roughly twice the mass of Neptune and 35 times the mass of Earth, and it takes 355 days to orbit its star, astronomers reported in a study published May 2 in The Astrophysical Journal Letters.

Despite its giant size, Kepler-139f had evaded detection, b'cos initial yield of NASA's Kepler space telescope, which discovered nearly 3,000 planets in its nine years of operation, relied on worlds transiting — passing between their star & Earth. The resulting dimming the star allowed astronomers to identify planets & calculate their size. Kepler couldn't see planets traveling above or below the wedge of space between it & the star, so any outliers remained unseen. But if the hidden world was part of a multiplanet system, astronomers could try to find it despite inclined orbit. Kepler-139 has 3 rocky transiting super-Earths; a 4th gas giant was later discovered. Gaps in their orbits suggested other worlds might be present. Precise measurements of orbits allowed astronomers to infer existence of at least one more planet...

A hidden 'super-Earth' exoplanet is dipping in and out of its habitable zone
(Main) an illustration of a massive exoplanet emerging friom stellar fog (inset) MP Mus and its protoplanetary disk as seen by ALMA. Astronomers discover monster exoplanet hiding in 'stellar fog' around young star. An NASA exoplanet-hunting spacecraft and citizen scientists discover a cool new alien world. Space.com videos. But if hidden world was part of a multiplanet system, astronomers could try to find it despite its inclined orbit. Kepler-139 has three rocky transiting super-Earths; a fourth gas giant was later discovered. Precise measurements of the orbits allowed the astronomers to infer the existence of at least one more planet. "The issue is not exactly finding non-transiting planets, but rather, finding situations in which we can deduce where non-transiting planet is located," Caleb Lammers, a graduate student in the Dept of Astrophysical Science @Princeton & co-author of the study, told Space.com by email.

Discovering Kepler-139f
Kepler's initial identification of a world was often followed up by observations from the ground. Using radial velocity (RV), astronomers could measure how much a planet tugged on its star, allowing them to determine the planet's mass. RV measurements could also reveal new worlds, as happened with the outermost gas giant, Kepler-139e.

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Introduce Oort Cloud—a region of icy debris located at the far edge of the our Solar System—explain why it is one of the most challenging astronomical structures to observe, due to its enormous distance & the faint sunlight it reflects. Analyze the challenges of directly observing the Oort Cloud, including the small size of its objects and the rapid diminution of sunlight with distance. Present the indirect evidence provided by long-period comets, and compare the Oort Cloud with closer structures like the asteroid belt and the Kuiper Belt to emphasize the differences. Also, discuss the role of mathematical models and computer simulations in confirming the existence of the Oort Cloud. Summarize by scientific significance of studying the Oort Cloud, highlighting how indirect evidence has broadened our understanding of universe. Additionally, outline prospects for future technological advancements and space missions aimed at directly observing this mysterious structure.

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Michio Kaku SHOCKED: Proxima B Just Confirmed Alien Life|. Renowned theoretical physicist Michio Kaku is in shock after NASA and the James Webb Space Telescope reportedly confirmed the most direct signs of alien life on Proxima B — closest to Earth-like planet 4 light year to our solar system. From mysterious biosignatures to unexplainable energy patterns & light anomalies, the evidence points toward one undeniable conclusion: we may not alone. Scientists around the world are calling this the beginning of a new era — one where first contact is no longer science fiction...but imminent reality.

Milky Way-type of galaxy found is much older than it should be - Earth.com https://share.google/EezIPwlvfRuSLV5dR

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Milky Way-type of galaxy found is much older than it should be - Earth.com https://share.google/EezIPwlvfRuSLV5dR

LUVOIR is bigger then JWST. It is built is yet to be place in space above earth.

Snapshot of Zhúlóng galaxy. Zhúlóng’s starlight travelled roughly 12.5 billion years be4 reaching JWST, offering an unprecedented look at spiral structure. The image reveals a compact, reddish core wrapped by bluish arms where younger stars reside, a pattern typical of mature disks, unprecedented so soon after cosmic dawn. At redshift 5.2 the cosmic baryon density was sixty‑three times today’s average, according to Planck cosmological parameters.

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Scientists confirm megathrust quake danger exists not only in southern B.C., but also in the north. Published: July 18, 2025

Following years of debate, scientists can now confirm that a fault zone off B.C.’s northern coast is capable of producing powerful megathrust earthquakes, the kind that can generate tsunamis.

The findings reveal what many researchers theorized: That the Pacific Plate is partially dipping beneath the North American Plate.

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Scientists confirm megathrust quake danger exists not only in southern B.C., but also in the north. Published: July 18, 2025

Following years of debate, scientists can now confirm that a fault zone off B.C.’s northern coast is capable of producing powerful megathrust earthquakes, the kind that can generate tsunamis. Findings reveal many researchers theorized: That the Pacific Plate is partially dipping beneath the North American Plate.

https://youtube.com/shorts/UYTSNdhXX0Y?s...dkQO8iDnHi

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That separation may sound modest, yet even a six-foot gap lets designers slide in upgrades, repairs, or entirely new hardware without cracking open a refrigerated chamber the size of a wardrobe. Flexibility beats brute-force scaling. Early roadmaps for quantum hardware leaned on cramming thousands of qubits onto a single platform. The physics community quickly learned that error rates ballooned as qubits multiplied, forcing ever-heavier error-correction overhead. Distributing processors flips that script. Each module can stay small enough for tight control & teleportation stitches operations together on demand.

Oxford quantum teleportation experiment. Only after the teleportation link was humming did the wider world learn who pulled it off: a team at Oxford University led by physicist Dougal Main.
“Previous demonstrations of quantum teleportation have focused on transferring quantum states between physically separated systems,” Dougal Main explains. “In our study, we use quantum teleportation to create interactions between these distant systems.”

The team’s setup entangled two ytterbium ions, fired off the required classical bits, and recreated a spin state on the far side with an 86 percent match.
That fidelity crossed the threshold for a basic logic gate, so the researchers ran a compact version of Grover’s search algorithm. Distributed gate delivered correct answer 71% of the time  respectable for early hardware crucially, limited more by local imperfections than by the teleportation itself.

Scientists have achieved a significant breakthrough by demonstrating quantum teleportation between two quantum computers for the first time. This accomplishment, achieved by researchers at University of Oxford, involves teleporting logical quantum gates across a network link, enabling distributed quantum computing. The experiment, detailed in Nature, utilized quantum entanglement to transfer information between processors, opening new possibilities for scalable quantum systems.

Applications: Next stage awaiting to
advancement has on potential to lead to the development of powerful quantum supercomputers, a new avenues for quantum communication.