i dont really know
The force between the two charged particles will be 100 times stronger when one particle has ten times as much charge as the other. This is because the force between two charged particles is directly proportional to the product of their charges.
Particles in a gas have the smallest size and are the most spread out, particles in a liquid are larger than in a gas and are more closely packed, and particles in a solid are the largest and are tightly packed in a regular pattern.
The motion of particles in a solid are much slower than those in the gas. Gaseous particles are very energetic and highly kinetic.
In a liquid forces are stronger.
A thermometer measures the amount of thermal energy a material has. This thermal energy is related to the vibrational and rotational energy the particles in the material have. By using the thermometer to measure the temperature of a material you are, in effect, measuring the amount of energy the particles of that material have.
The force between the two charged particles will be 100 times stronger when one particle has ten times as much charge as the other. This is because the force between two charged particles is directly proportional to the product of their charges.
Magnetic force is the force that acts on a moving charged particle in a magnetic field, while electric force is the force that acts on a charged particle due to the presence of an electric field. The main difference between the two is that magnetic force only affects moving charged particles, while electric force can act on both moving and stationary charged particles. In terms of their effects on charged particles, magnetic force can change the direction of the particle's motion, while electric force can change both the direction and speed of the particle. Additionally, electric force is typically stronger than magnetic force for most everyday situations.
The electric force is much stronger than the gravitational force, typically by a factor of around 10^36. This is because electric forces involve interactions between charged particles, which are inherently stronger than interactions between particles that only have mass.
The mass and size of an alpha particle compare with the masa and size of beta particle in the sense that the alpha particle is significantly larger in both size and mass that the beta and gamma particles. This is why it is called the alpha particle.
Particles in a gas have the smallest size and are the most spread out, particles in a liquid are larger than in a gas and are more closely packed, and particles in a solid are the largest and are tightly packed in a regular pattern.
The motion of particles in a solid are much slower than those in the gas. Gaseous particles are very energetic and highly kinetic.
1. A cloud chamber can be used to detect alpha or beta particle radiation. A cloud chamber is filled with water or ethanol vapor. When radioactive sample is placed in the cloud the chamber gives off charged alpha or beta particles that travel through the water or ethanol vapor. -B0N3S
The easiest way to distinguish between volcanic ash and volcanic dust particles is to compare their diameter. Seismographs can be useful in predicting volcanic eruptions because they measure earthquake activity.
For the same material, at a higher temperature the particles will move faster.However, if you compare different materials, it is more complicated. The temperature is more closely related to the average energy per particle and per degree of freedom.
For the same material, at a higher temperature the particles will move faster.However, if you compare different materials, it is more complicated. The temperature is more closely related to the average energy per particle and per degree of freedom.
The wave model of light describes light as an electromagnetic wave that exhibits properties like interference and diffraction. The particle model of light, on the other hand, describes light as a stream of particles called photons. Phenomena like the photoelectric effect and Compton scattering can only be explained by the particle model of light, where light behaves as discrete particles (photons) interacting with matter.
They have opposite charges.