An unbalanced force causing a change in velocity could be a car accelerating when the driver presses the gas pedal. The force from the engine is greater than the opposing forces such as friction and air resistance, resulting in the car's velocity increasing.
The unbalanced charge on an object refers to an excess of either positive or negative charges on the object, causing it to have an overall charge imbalance. This can occur through processes like friction, induction, or contact with charged objects, leading to the accumulation of more electrons (negative charge) or protons (positive charge) on the object.
In an electrical system where current is equal to the charge multiplied by the velocity, the relationship is that the current flowing through the system is directly proportional to both the amount of charge and the velocity at which the charge is moving. This means that as either the charge or the velocity increases, the current flowing through the system will also increase.
If unbalanced forces are applied to an object, the object will experience acceleration in the direction of the net force. This acceleration will cause the object's velocity to change, leading to either an increase or decrease in speed or a change in direction. The object will continue to move until the forces acting on it are balanced.
To find velocity with charge and joules, you would need additional information such as the mass of the object or particle carrying the charge. Once you have the mass, you can use the formula for kinetic energy, which incorporates velocity, charge, and energy (in joules) as factors to solve for velocity.
That depends on the exact situation. If there is an interaction with other charges, this can cause the object to acceleration (basically, change its velocity), and the greater the object's charge, the faster its velocity will change.
The unbalanced charge on an object refers to an excess of either positive or negative charges on the object, causing it to have an overall charge imbalance. This can occur through processes like friction, induction, or contact with charged objects, leading to the accumulation of more electrons (negative charge) or protons (positive charge) on the object.
In an electrical system where current is equal to the charge multiplied by the velocity, the relationship is that the current flowing through the system is directly proportional to both the amount of charge and the velocity at which the charge is moving. This means that as either the charge or the velocity increases, the current flowing through the system will also increase.
If unbalanced forces are applied to an object, the object will experience acceleration in the direction of the net force. This acceleration will cause the object's velocity to change, leading to either an increase or decrease in speed or a change in direction. The object will continue to move until the forces acting on it are balanced.
What you are describing is a polar covalent bond. In which the bonded atoms have an unequal attraction for the shared electron and an unbalanced distribution of charge results. An example is HCl - the shared electron oscillates between the bonded atoms. The resulting partial charges are a property only of zones within the distribution, and not the assemblage as a whole.
To find velocity with charge and joules, you would need additional information such as the mass of the object or particle carrying the charge. Once you have the mass, you can use the formula for kinetic energy, which incorporates velocity, charge, and energy (in joules) as factors to solve for velocity.
That depends on the exact situation. If there is an interaction with other charges, this can cause the object to acceleration (basically, change its velocity), and the greater the object's charge, the faster its velocity will change.
A lack of electrons causing a positive charge, or too many electrons causing a negative charge.
Polar, because it contains unbalanced polar bonds.
The magnitude of drift velocity is small because it represents the average velocity of charge carriers in a material experiencing an electric field. The individual charge carriers move at high speeds, but they collide frequently with atoms in the material, leading to a net low average velocity. The drift velocity is proportional to the strength of the electric field and inversely proportional to the charge carrier's mobility and the charge density.
We use the term net charge to define current due to unbalanced charges that flow.
No, the velocity of an oscillating charge remains constant as it moves to and fro in a wire, assuming no external forces act on the charge. The charge simply changes direction as it moves back and forth between the ends of the wire.
2 unbalanced electrons have a 2- charge on the molecule/atom