• P (Polynomial time): Class of problems solvable in polynomial time by a deterministic Turing machine — i.e., efficiently solvable.

• NP (Non-deterministic Polynomial time): Class of problems where a proposed solution can be verified in polynomial time — even if we don’t know how to find it efficiently. These include things like the traveling salesman, boolean satisfiability, etc.

The P vs NP question asks:

"If a solution can be quickly verified, can it also be quickly found?"

If P = NP, it would mean all problems whose answers we can verify quickly, we can also solve quickly. That would upend cryptography, optimization, AI... basically modern life.

If P ≠ NP, then there exist problems where verifying is easy, but solving is fundamentally hard — meaning there are limits to what computers can ever efficiently compute.

Sputnik 1, launched by the Soviet Union (USSR) in 1957

Gravitational Potential Energy (Classical):

For two masses, m1m_1m1 and m2m_2m2, separated by a distance rrr, the gravitational potential energy UUU is given by the classical equation:

U=−Gm1m2rU = - \frac{G m_1 m_2}{r}U=−rGm1m2

Where:

• GGG is the gravitational constant,

• m1m_1m1 and m2m_2m2 are the masses of the two objects,

• rrr is the distance between them.

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• 2.Effect of a Relativistic Speed:
  When one of the particles moves at relativistic speeds (near the speed of light), we need to account for relativistic effects. Classical physics alone won't be enough because relativity changes our understanding of both energy and gravity.

  • In relativity, energy is conserved, but the total energy includes both kinetic energy and rest energy. The relativistic kinetic energy is given by:

• K=(γ−1)mc2K = (\gamma - 1) m c^2K=(γ−1)mc2

  Where:

  • γ=11−v2/c2\gamma = \frac{1}{\sqrt{1 - v^2/c^2}}γ=1−v2/c21 is the Lorentz factor,

  • vvv is the speed of the moving particle,

  • ccc is the speed of light,

  • mmm is the mass of the moving object.

• This energy increases significantly as the speed approaches the speed of light.

• Relativistic Gravitational Energy:

  To fully describe the gravitational potential energy in a relativistic context, we must consider that gravity itself becomes affected by relativistic speeds. Specifically, the gravitational field is non-static and dynamic in relativity, which means the curvature of spacetime needs to be accounted for, especially at high speeds or near massive objects.

  At relativistic speeds, the gravitational potential energy should still follow the classical formula for large distances, but the dynamics of spacetime (how mass distorts space) must be considered for more accurate modeling (such as in General Relativity). In some extreme cases (like near black holes), energy in gravitational fields becomes more complex to compute due to the warping of spacetime.

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  • Classical energy: The potential energy between two masses m1m_1m1 and m2m_2m2 at distance rrr is U=−Gm1m2rU = - \frac{G m_1 m_2}{r}U=−rGm1m2.

• 
  

  • Relativistic energy: When one particle moves at relativistic speeds, its kinetic energy increases dramatically as its velocity approaches the speed of light, affecting the total energy of the system.

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  • The gravitational energy doesn’t fundamentally change unless we move to extremely high masses or speeds, but relativity modifies the dynamics of gravitational fields (especially in high-gravity environments like near black holes or neutron stars).

What is the Kazungula Quadripoint (Botswana, Namibia, Zambia, and Zimbabwe — though it's debated due to a narrow river border)?

What is the Defenestration of Prague?