vincentm said:According to Relativity, if a ship traveling at nearly the speed of light through interstellar space diffuse atoms (mostly Hydrogen, becase simply that is the most abundant atom in the universe, right?) would strike the front of the ship with increased mass, causing radiation. My question is how is this mass increased on the part of the atom?
Thank in advance guys
The change in mass is due, not to the stucture of the atom (or any particle for that matter) but is due strictly due to a combination of Lorentz contraction and time dilation. Recall that there is a frame in which the atom is at rest and in that frame the particle has a given structure which will not change when your frame of reference changes.vincentm said:According to Relativity, if a ship traveling at nearly the speed of light through interstellar space diffuse atoms (mostly Hydrogen, becase simply that is the most abundant atom in the universe, right?) would strike the front of the ship with increased mass, causing radiation. My question is how is this mass increased on the part of the atom?
Thank in advance guys
vincentm said:According to Relativity, if a ship traveling at nearly the speed of light through interstellar space diffuse atoms (mostly Hydrogen, becase simply that is the most abundant atom in the universe, right?) would strike the front of the ship with increased mass, causing radiation. My question is how is this mass increased on the part of the atom?
Thank in advance guys
Interstellar travel refers to the act of traveling between stars in different planetary systems. It involves traveling vast distances through the vacuum of outer space.
Interstellar travel is difficult due to several factors, such as the vast distances between stars, the lack of established transportation systems, and the challenges of sustaining human life in space for long periods of time.
Some proposed solutions to the difficulties with interstellar travel include developing advanced propulsion systems, creating self-sustaining spacecraft, and using wormholes or other theoretical methods of faster-than-light travel.
The potential risks of interstellar travel include exposure to high levels of radiation, encountering unknown or hostile alien life forms, and technical malfunctions that could result in the failure of the mission.
Although significant progress has been made in the field of space exploration, we are still far from achieving interstellar travel. The technology and resources required for such a feat are currently beyond our reach, but ongoing research and advancements may bring us closer to this goal in the future.