High School can be like that 😅🏈 #shorts

"nice work out there son" "you too dad" ahh moment

Nontoxicz

And then next year those 18 year olds are lined up against two 26 year olds on their 8th year of eligibility with 2 kids and a mortgage 💀

mraverageconsumer

I remember staring my sophomore year for varsity and there’s a clip of me running up to blitz then getting absolutely bulldozed by a 6, 2 linemen. I probably hit puberty that same night. Love the game

lmaurbrisko

Lmfao this is so real. I'm a freshman, and we play JV teams and in Wisconsin you can bring down players from varsity to play JV. I was 15 5'8 180 lbs LT, and the d lineman was 6'4 250 lbs and 17 yo.

Ivacko

LAND OF 1000 DANCES‼️‼️‼️‼️ LETS GOOO‼️‼️‼️‼️ one of my absolute fav stand tunes to play during football games

iluvvaporeonmain

Land of 1000 dances in the back is so real

Your_local_block_of_ramen

The memories of play land of 1000 dances at football games

devenbarrow

For those who don't understand...




Nuclear fusion is a process in which two light atomic nuclei combine to form a heavier nucleus, releasing a tremendous amount of energy. This is the same process that powers the Sun and other stars, as well as hydrogen bombs. The key feature of nuclear fusion is that the mass of the resulting nucleus is slightly less than the combined mass of the original nuclei, and this "missing" mass is converted into energy according to Einstein's famous equation, \( E = mc^2 \).

For fusion to occur, the two nuclei must come extremely close together. However, atomic nuclei are positively charged, so they repel each other due to electrostatic forces (Coulomb repulsion). To overcome this, the nuclei need to be moving at very high speeds, typically achieved by extremely high temperatures (millions of degrees Celsius) and pressures.

In stars, such as our Sun, fusion happens at temperatures around 15 million degrees Celsius (27 million degrees Fahrenheit) and under immense pressure. These conditions cause atoms to move fast enough to collide with each other with enough force to overcome their electrostatic repulsion. The most common fusion reaction in stars, including the Sun, involves two isotopes of hydrogen — deuterium (a hydrogen isotope with one proton and one neutron) and tritium (a hydrogen isotope with one proton and two neutrons). When these two nuclei fuse, they form a helium nucleus (two protons and two neutrons) and release a large amount of energy in the form of light and heat.
The energy produced in fusion comes from the difference in mass between the reactants and products. The mass of the helium nucleus and the free neutron produced is slightly less than the combined mass of the deuterium and tritium nuclei. This "lost" mass is released as energy, in accordance with Einstein’s equation.

Nuclear fusion has the potential to be a nearly limitless and clean source of energy. If harnessed effectively, fusion could provide abundant fuel since hydrogen is the most abundant element in the universe, and isotopes like deuterium and tritium can be extracted from water and lithium. Fusion also doesn’t produce long-lived radioactive waste like nuclear fission (the process used in nuclear reactors), and it doesn’t emit greenhouse gases. Moreover, fusion reactions are inherently safer than fission because they don't create a chain reaction that could runaway, and the process doesn't involve highly radioactive materials.

While nuclear fusion holds great promise, achieving controlled fusion on Earth is incredibly challenging. The conditions needed for fusion — extremely high temperatures (millions of degrees), high pressure, and confinement of the plasma — are difficult to create and maintain. To date, scientists have struggled to achieve net positive energy from fusion (more energy produced than consumed) in a controlled manner. Current experimental reactors like ITER (International Thermonuclear Experimental Reactor) in France and others like NIF (National Ignition Facility) in the U.S. are working to develop fusion energy, but commercial fusion power plants are likely still decades away from being realized.

In summary, nuclear fusion is the process that powers the stars, and its potential for clean, abundant energy on Earth is immense — but the technical challenges to making fusion practical for power generation remain formidable.

Noasuuu

That's why freshman are rarely put on Varsity

Dck_mtnaslt

i was on my high schools varsity soccer team in 8th grade... i play striker and i still dont know how im alive today after some of those collisions 😭

Nightspeed_

I’m a Sophmore and started 4 games I can relate big time

WaybetterthanBron

I’m 14 doin that going onto 15 next season for varsity

Munchy

Sometimes you're little fish, Sometimes you're big fish.

maureendunnagan

I started on varsity as a sophomore. I understand, sir.

dv

I was getting rides all the way through high school lmao

kamp

our qb was a freshman...we didn't win a single game. most points we scored was 13 😭😑

edenclarke_

That’s what you should aim for. I remember playing city league and we played a team that were full of kids who were 2 years older. We got our ass whooped, but it definitely unleashed a dog inside me. Winning is the goal, but when you embrace the challenge that’s when you grow

Eldrvck

What is this band arrangement this is a bop

am-rv

PLEASE! I’m 12 in 7th grade and was pulled up to be a starter on my high school varsity soccer team.
Edit: I have created a war of whether or not I’m lying 🤣

JuliaSoccer

(actually most states do not allow fresh 18 year olds to adopt anyone unless you are related and able to financially care for them, learned through experience)

Demonspaces