Exploring Planetary Orbits and Their Alignment

Due to the sun's gravitational pull

Because of the initial spherical shape of the gas cloud

Resulting from the conservation of angular momentum during formation

Influence of external star systems

Impact with another galaxy

Formation of a black hole nearby

A nearby supernova explosion

Sudden increase in dark matter density

The idea that momentum is not conserved in space

A principle that dictates that planets must orbit in circles

A theory about the conservation of energy in planetary orbits

A physical law stating that the total angular momentum of a system remains constant if no external torques are applied

It forms multiple small clouds

It expands and cools down

It flattens into a disk

It spins slower and disperses

Observations of disk around young stars

Computer simulations of galaxy formation

Historical records of ancient astronomers

Theoretical calculations without observational evidence

Through direct travel to the disks

By observing similar formations around young stars

Using theoretical physics only

Studying ancient astronomical texts

Due to the sun's rotational direction

They formed from the same rotating disk

Random distribution of orbits

Magnetic fields in the solar system