A bicyclist is stopped at the entrance to a valley, as sketched below: E C olo D Where would the bicyclist have the highest potential energy? (choose one) v Where would the bicyclist have the lowest potential energy? (choose one) v Where would the bicyclist have the highest kinetic energy? ( choose one) Where would the bicyclist have the highest speed? (choose one) v Would the bicyclist's kinetic energy be higher at B or C? (choose one) Would the bicyclist's potential energy be higher at B or C? (choose one) Would the bicyclist's total energy be higher at B or C? (choose one) Suppose the bicyclist lets off the brakes and coasts down into the valley without pedaling

A bicyclist is stopped at the entrance to a valley, as sketched below: E C olo D Where would the bicyclist have the highest potential energy? (choose one) v Where would the bicyclist have the lowest potential energy? (choose one) v Where would the bicyclist have the highest kinetic energy? ( choose one) Where would the bicyclist have the highest speed? (choose one) v Would the bicyclist's kinetic energy be higher at B or C? (choose one) Would the bicyclist's potential energy be higher at B or C? (choose one) Would the bicyclist's total energy be higher at B or C? (choose one) Suppose the bicyclist lets off the brakes and coasts down into the valley without pedaling. Even if there is no friction or air resistance to slow her down, what is the farthest point the (choose one) v bicyclist could reach without pedaling? X ?