Two cars collide at an icy intersection and stick together afterward. The first car has a...

Two cars collide at an icy intersection and stick together afterward. The first car has a...

Two cars collide at an icy intersection and stick together afterward. The first car has a mass of 1050 kg and was approaching at 9.00 m/s due south. The second car has a mass of 800 kg and was approaching at 20.0 m/s due west. (a) Calculate the final velocity of the cars. (Note that since both cars have an initial velocity, you cannot use the equations for conservation of momentum along the x-axis and y-axis; instead, you must look...

Two cars collide at an icy intersection and stick together afterward. The first car has a...

Two cars collide at an icy intersection and stick together afterward. The first car has a mass of 1300 kg and was approaching at 5.00 m/s due south. The second car has a mass of 900 kg and was approaching at 23.0 m/s due west. (a) Calculate the final velocity (magnitude in m/s and direction in degrees counterclockwise from the west) of the cars. (Note that since both cars have an initial velocity, you cannot use the equations for conservation...

Two cars collide at an icy intersection and stick together afterward. The first car has a...

Two cars collide at an icy intersection and stick together afterward. The first car has a mass of 1650 kg and was approaching at 5.00 m/s due south. The second car has a mass of 700 kg and was approaching at 18.0 m/s due west. (a) Calculate the final velocity of the cars (In m/s). (Note that since both cars have an initial velocity, you cannot use the equations for conservation of momentum along the x-axis and y-axis; instead, you...

Two cars collide at an icy intersection and stick together afterward. The first car has a...

Two cars collide at an icy intersection and stick together afterward. The first car has a mass of 1500 kg and was approaching at 4.00 m/s due south. The second car has a mass of 700 kg and was approaching at 18.0 m/s due west. (a) Calculate the final velocity of the cars. (Note that since both cars have an initial velocity, you cannot use the equations for conservation of momentum along the x-axis and y-axis; instead, you must look...

Two cars collide at an icy intersection and stick together afterward. The first car has a...

Two cars collide at an icy intersection and stick together afterward. The first car has a mass of 1650 kg and was approaching at 4.00 m/s due south. The second car has a mass of 700 kg and was approaching at 18.0 m/s due west. (a) Calculate the final velocity of the cars. (Note that since both cars have an initial velocity, you cannot use the equations for conservation of momentum along the x-axis and y-axis; instead, you must look...

Two cars collide at an icy intersection and stick together afterward. The first car has a...

Two cars collide at an icy intersection and stick together afterward. The first car has a mass of 1100 kg and is approaching at 9.5 m/s due south. The second car has a mass of 950 kg and is approaching at 15 m/s due west. Part (a) Calculate the magnitude of the final velocity, in meters per second, of the cars. Part (b) Calculate the direction of the final velocity, in degrees south of west, of the cars. Part (c)...

Two cars collide at an icy intersection and stick together afterward. The first car has a...

Two cars collide at an icy intersection and stick together afterward. The first car has a mass of 1500 kg and is approaching at 9.5 m/s due south. The second car has a mass of 750 kg and is approaching at 17 m/s due west. A) Calculate the magnitude of the final velocity, in meters per second, of the cars. B) Calculate the direction of the final velocity, in degrees, south of west of the cars. C) What's the change...

Two cars collide at an icy intersection and stick together afterward. The first car has a...

Two cars collide at an icy intersection and stick together afterward. The first car has a mass of 1350 kg and is approaching at 9.5 m/s due south. The second car has a mass of 750 kg and is approaching at 17.5 m/s due west. Part (a) Calculate the magnitude of the final velocity, in meters per second, of the cars. Part (b) Calculate the direction of the final velocity, in degrees south of west, of the cars. Part (c)...

Two cars collide at an icy intersection and stick together afterward. The first car has a...

Two cars collide at an icy intersection and stick together afterward. The first car has a mass of 1250 kg and is approaching at 6.5 m/s due south. The second car has a mass of 750 kg and is approaching at 17 m/s due west. a.) Calculate the magnitude of the final velocity, in meters per second, of the cars. b.) Calculate the direction of the final velocity, in degrees south of west, of the cars. c.) What is the...

Two cars collide at an icy intersection and stick together afterward. The first car has a...

Two cars collide at an icy intersection and stick together afterward. The first car has a mass of 1250 kg and is approaching at 9.5 m/s due south. The second car has a mass of 550 kg and is approaching at 17 m/s due west.Calculate the direction of the final velocity, in degrees south of west, of the cars.What is the change in kinetic energy, in joules, for the collision? (This energy goes into deformation of the cars.)