Please Vote for me on the TikTok Awards🥹 1️⃣Open TikTok 2️⃣Search “TikTok Awards” 3️⃣Click on Sports Creator of the year You can vote once a day, everyday!🥰🤸♀️
That's cool anyways, here's how to build a particle accelerator: 1. Get a Particle Source: To start, you need a source of charged particles. Protons are a common choice, and they can be created by stripping electrons from hydrogen atoms, leaving positively charged protons behind. Alternatively, you could use electrons, which can be generated using a simple cathode or electron gun. The type of particle you choose depends on the kind of experiments or applications you have in mind. 2. Build a Vacuum Chamber: The particle accelerator needs a vacuum environment for particles to travel without hitting air molecules. Even small interactions with air can slow the particles down or knock them off course. To create this, build a long, sealed metal tube and use vacuum pumps to remove as much air as possible, achieving near-vacuum conditions. This tube is where the particles will travel during acceleration. 3. Install Electromagnets for Steering and Focusing: Charged particles don’t naturally travel in straight lines, so electromagnets are used to steer and focus the particle beam. Wrap copper wire into coils (solenoids) or use specialized electromagnets around sections of the vacuum chamber. These magnets will bend and direct the particles, especially in circular or curved accelerators like a cyclotron or synchrotron. The magnets also focus the beam so it doesn't spread out as it travels. 4. Add RF Cavities for Acceleration: The particles need to be accelerated to near the speed of light for many experiments. This is done using radio frequency (RF) cavities, which create oscillating electric fields. As particles pass through each cavity, the field gives them an extra "kick" of energy, speeding them up. You need to set up multiple RF cavities along the vacuum tube if you’re building a linear accelerator, or place them strategically in circular designs like synchrotrons to increase the particles’ energy with every lap. 5. Set Up a High-Voltage Power Supply: To power the RF cavities and electromagnets, you’ll need a high-voltage power supply. It must be carefully controlled and synchronized to ensure that the RF fields accelerate the particles at the right time, and that the electromagnets are properly tuned to guide them. Depending on the scale of your accelerator, the power requirements could be substantial. 6. Install Detectors to Measure Particles: Once the particles are moving at high speeds, you’ll want to monitor their behavior, especially if you're aiming for collisions. Detectors are placed around the end of the accelerator or at key points where the particle beam will interact with targets. These detectors can measure things like particle energy, trajectories, or the results of particle collisions if you’re performing experiments. 7. Add Cooling Systems: If your accelerator is large or uses superconducting magnets, you’ll need cooling systems, such as liquid helium, to keep the magnets at cryogenic temperatures. Superconductors lose all electrical resistance at these temperatures, allowing for extremely efficient and powerful magnets. Even if your setup doesn’t require superconductors, cooling may be necessary to prevent overheating in the RF cavities and electromagnets. 8. Set Up a Computer-Controlled System: Since many aspects of the accelerator need precise timing and synchronization, you’ll need a computer to control the RF cavities, power supply, and magnets. The system will automatically adjust the power and electromagnetic fields in real-time to ensure the particles remain on track and accelerate smoothly. This computer also collects data from the detectors and can adjust the experiment based on results. 9. Test and Calibrate the System: Once everything is in place, it’s time to test the accelerator. Initially, you’ll fire low-energy particles through the system to check if the vacuum, magnets, and RF cavities are working correctly. You may need to tweak the alignment of the magnets and fine-tune the power settings to ensure the particle beam accelerates efficiently. During this stage, data from the detectors will help you see if the particles are reaching the expected speeds. 10. Run Experiments or Particle Collisions: Once the accelerator is fully functional, you can start running experiments. In a particle collider, for example, you can direct two particle beams to collide at extremely high speeds, creating conditions similar to those just after the Big Bang. The detectors will capture the resulting particles and interactions, allowing you to study fundamental physics. If you’re not colliding particles, you can still study their behavior at high speeds or use them to hit a specific target.
I'm no gymnast at all but from what I saw in the video at the start I'd say you got hit on the head because different to the video Joe kept his leg apart the whole time. The man in the video actually tucked them in when he was in the air. I have literally no clue how it physically works but it is very cool and you did an good attempt 😊
The guy in the video flipped almost on the spot rather than forward. That might make the timing a bit easier (still insane though 😂😂😂😂😂 I could never do that). Will done - you were so close.
@@LucieColebeck23The flipper has to START AND LAND with their legs spread. The person going thru the hoop jumps thru the flipper's legs first then the hoop n lands back between their legs. Lucie was jumping too late. (Not saying i could do it just the observation i made lol) U guys will get it tho ur awesome!!😊
In the inspiration video she starts her dive almost drive thru his legs and plants/ bounces for the flips, so both his landing and takeoff need to be with his legs apart
The flipper has to START AND LAND with their legs spread. The person going thru the hoop jumps thru the flipper's legs first then the hoop n lands back between their legs. The girl here was jumping too late. (Not saying i could do it just the observation i made lol) U guys will get it tho ur awesome!!😊
I know litetally nothing about gymnastics and tumbling but I think it would be wiser to have the shorter one jump through the hoop instead 😭 my logic is the one holding the hoop needs to have long enough legs that the shorter one can still jump through the gap, and having a shorter person jump through the hoop would mean they could get through the hoop in less time (longer person = longer legs = more time to catch feet on the hoop)
It's not working because she's too afraid of hurting herself and so isn't committing to it. You can see how tense she is. There's no way it'll work until they both loosen up and completely go for it
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Please Vote for me on the TikTok Awards🥹
1️⃣Open TikTok
2️⃣Search “TikTok Awards”
3️⃣Click on Sports Creator of the year
You can vote once a day, everyday!🥰🤸♀️
Not me realizing that that is the circus school I train at and I have met those people...
woww
How much did they practice to get that perfect?
This is so cool!😅🤩
Isn’t it a gymnastics gym?
@@Isla-sn9xjthats what i was thinking.. maybe they use some of the equipment to practice for circus things?
Again you guys are so talented
🥹🥹
"But then on our last attempt, *this* happened..."
"OOOoooOoOf"
You're so underrated!! Your effort is admirable ✨️👏
This is so kind, thank you!🥹🥰
I’m so glad that the last attempt wasn’t perfect. Idk it just feels more real
You backing out is like me when I try to dive… good work, you guys were so close!
😂😂 it’s so scary
😂😂 are you guys okay?!
Yess, we're all good😆
That's cool anyways, here's how to build a particle accelerator:
1. Get a Particle Source: To start, you need a source of charged particles. Protons are a common choice, and they can be created by stripping electrons from hydrogen atoms, leaving positively charged protons behind. Alternatively, you could use electrons, which can be generated using a simple cathode or electron gun. The type of particle you choose depends on the kind of experiments or applications you have in mind.
2. Build a Vacuum Chamber: The particle accelerator needs a vacuum environment for particles to travel without hitting air molecules. Even small interactions with air can slow the particles down or knock them off course. To create this, build a long, sealed metal tube and use vacuum pumps to remove as much air as possible, achieving near-vacuum conditions. This tube is where the particles will travel during acceleration.
3. Install Electromagnets for Steering and Focusing: Charged particles don’t naturally travel in straight lines, so electromagnets are used to steer and focus the particle beam. Wrap copper wire into coils (solenoids) or use specialized electromagnets around sections of the vacuum chamber. These magnets will bend and direct the particles, especially in circular or curved accelerators like a cyclotron or synchrotron. The magnets also focus the beam so it doesn't spread out as it travels.
4. Add RF Cavities for Acceleration: The particles need to be accelerated to near the speed of light for many experiments. This is done using radio frequency (RF) cavities, which create oscillating electric fields. As particles pass through each cavity, the field gives them an extra "kick" of energy, speeding them up. You need to set up multiple RF cavities along the vacuum tube if you’re building a linear accelerator, or place them strategically in circular designs like synchrotrons to increase the particles’ energy with every lap.
5. Set Up a High-Voltage Power Supply: To power the RF cavities and electromagnets, you’ll need a high-voltage power supply. It must be carefully controlled and synchronized to ensure that the RF fields accelerate the particles at the right time, and that the electromagnets are properly tuned to guide them. Depending on the scale of your accelerator, the power requirements could be substantial.
6. Install Detectors to Measure Particles: Once the particles are moving at high speeds, you’ll want to monitor their behavior, especially if you're aiming for collisions. Detectors are placed around the end of the accelerator or at key points where the particle beam will interact with targets. These detectors can measure things like particle energy, trajectories, or the results of particle collisions if you’re performing experiments.
7. Add Cooling Systems: If your accelerator is large or uses superconducting magnets, you’ll need cooling systems, such as liquid helium, to keep the magnets at cryogenic temperatures. Superconductors lose all electrical resistance at these temperatures, allowing for extremely efficient and powerful magnets. Even if your setup doesn’t require superconductors, cooling may be necessary to prevent overheating in the RF cavities and electromagnets.
8. Set Up a Computer-Controlled System: Since many aspects of the accelerator need precise timing and synchronization, you’ll need a computer to control the RF cavities, power supply, and magnets. The system will automatically adjust the power and electromagnetic fields in real-time to ensure the particles remain on track and accelerate smoothly. This computer also collects data from the detectors and can adjust the experiment based on results.
9. Test and Calibrate the System: Once everything is in place, it’s time to test the accelerator. Initially, you’ll fire low-energy particles through the system to check if the vacuum, magnets, and RF cavities are working correctly. You may need to tweak the alignment of the magnets and fine-tune the power settings to ensure the particle beam accelerates efficiently. During this stage, data from the detectors will help you see if the particles are reaching the expected speeds.
10. Run Experiments or Particle Collisions: Once the accelerator is fully functional, you can start running experiments. In a particle collider, for example, you can direct two particle beams to collide at extremely high speeds, creating conditions similar to those just after the Big Bang. The detectors will capture the resulting particles and interactions, allowing you to study fundamental physics. If you’re not colliding particles, you can still study their behavior at high speeds or use them to hit a specific target.
cool, thx
You need to tuck in less. Its really hard. But you need to slow the rotation of the hoop.
Yh she weren't really jumping at the right time as well but they're really good anyways❤
I'm no gymnast at all but from what I saw in the video at the start I'd say you got hit on the head because different to the video Joe kept his leg apart the whole time. The man in the video actually tucked them in when he was in the air. I have literally no clue how it physically works but it is very cool and you did an good attempt 😊
Me thinking I could casually do a front flip
I heard that snap at the end
I felt the pain through the phone 😂
You should try an hair slick stick!!!
The guy in the video flipped almost on the spot rather than forward. That might make the timing a bit easier (still insane though 😂😂😂😂😂 I could never do that). Will done - you were so close.
Yess! This is very true. I will try this in part 2☺️
@@LucieColebeck23The flipper has to START AND LAND with their legs spread. The person going thru the hoop jumps thru the flipper's legs first then the hoop n lands back between their legs. Lucie was jumping too late. (Not saying i could do it just the observation i made lol) U guys will get it tho ur awesome!!😊
You just need to slow the rotation of the flip.😊
I hope you get it.🙏🤞
Thanks! Will definitely give this a go in part 2😆
i have faith in y’all!
In the inspiration video she starts her dive almost drive thru his legs and plants/ bounces for the flips, so both his landing and takeoff need to be with his legs apart
The flipper has to START AND LAND with their legs spread. The person going thru the hoop jumps thru the flipper's legs first then the hoop n lands back between their legs. The girl here was jumping too late. (Not saying i could do it just the observation i made lol) U guys will get it tho ur awesome!!😊
Hiiiiii Lucie 😊 I’m glad to see you!!!!
Hiiii😆
@ do you remember me
HI LUCIE!!
Hiiiii
@ i love watching your cirque de soleii and trying olimpic skills videos! i've been a gymnast for 12 years!
How r u guys so talented like bro all I can do is a roundoff lol😂😂😂
I am a gymnast and my gym has those same mats ❤😅
please land on your hands first then feet not the super man death dive practice quadrobics it will help with carpet burn
I know litetally nothing about gymnastics and tumbling but I think it would be wiser to have the shorter one jump through the hoop instead 😭 my logic is the one holding the hoop needs to have long enough legs that the shorter one can still jump through the gap, and having a shorter person jump through the hoop would mean they could get through the hoop in less time (longer person = longer legs = more time to catch feet on the hoop)
Some show this to Nile Wilson 😂
Keep trying you were so close 👍
It’s wasn’t working because she was not jumping
Yikes, that looks like it could go wrong badly 🙃
It's not working because she's too afraid of hurting herself and so isn't committing to it. You can see how tense she is. There's no way it'll work until they both loosen up and completely go for it
Succesful fail 💀
make a santa emoji with him eating cookies with milk because it’s almost christmas 🎅 🎄
❤❤❤❤
Secomd
is he okay??????
Omg is joe ok 😮😮😮😮😮😮😮😮😮
😂half way✌️ only the other to go through now
Joe it's hannah
🎉🎉
Good job jo not good girl
😭😭
FIRST
Yayyy hiiii
SECOND!!
Uhh