Variable speed rotor with slow rotation mode

What is claimed is: 1. A vehicle, comprising: an electric motor system including a motor coupled to an anti-torque rotor, wherein the motor is configured, when turned-on, to drive the anti-torque rotor at a rotational rate that will create thrust; and a controller connected to the motor to control the motor to drive the anti-torque rotor, when the motor system is energized and the motor is turned-off, at least at a minimum rotation rate greater than zero and less than a rotation rate that will create thrust; and a manual override switch located proximate to the anti-torque rotor, the manual override switch operable to stop the rotation of the anti-torque rotor. 2. The vehicle of claim 1 , wherein the minimum rotation rate is approximately 5 revolutions per minute (RPM) or less. 3. The vehicle of claim 1 , wherein the minimum rotation rate is in a range of approximately 0.5 revolutions per minute (RPM) and 3 RPM. 4. An aircraft, comprising: an electric motor system including a motor coupled to an anti-torque rotor; a controller connected to the motor to control the motor to drive the anti-torque rotor at a rotation rate that will create thrust when the motor is turned-on and to control the motor to drive the anti-torque rotor at least at a minimum rotation rate greater than zero and less than a rotation rate that will create thrust when the motor system is electrically energized by the electric power source and the motor is turned-off; and a manual override switch located proximate to the anti-torque rotor, the manual override switch operable to stop the rotation of the anti-torque rotor. 5. The aircraft of claim 4 , wherein the anti-torque rotor arranged in an electric anti-toque distributed system. 6. The aircraft of claim 4 , wherein the aircraft is a helicopter. 7. The aircraft of claim 4 , wherein the manual override switch is positioned within approximately three feet or less from a center of the anti-torque rotor. 8. A method, comprising: controlling a rotation rate of an anti-torque rotor in a vertical takeoff and landing (VTOL) aircraft, wherein the anti-torque rotor is driven by a motor of an electric motor system; detecting that the motor system is electrically energized and that the motor is turned-off; controlling the motor to drive the anti-torque rotor at a minimum rotation rate that is greater than zero and less than a rotation rate that will create thrust in response to detecting that the motor system is electrically energized and that the motor is turned-off; and stopping rotation of the anti-torque rotor in response to a person manually holding a manual override switch, that is positioned proximate to the anti-torque rotor, in an override position. 9. The method of claim 8 , wherein the VTOL aircraft is a helicopter. 10. The method of claim 8 , wherein the anti-torque rotor is arranged in an electric distributed rotor system. 11. The method of claim 8 , wherein the manual override switch is positioned within approximately three feet or less from the anti-torque rotor.