Method and apparatus for fast gas exchange, fast gas switching, and programmable gas delivery

What is claimed is: 1. A method of supplying gases to a process chamber, comprising: supplying a first process gas to the process chamber from a first gas panel through a first fast gas exchange module during a first process, comprises selectively diverting the first process gas from a first flow controller through a second flow controller to the process chamber or an exhaust, or selectively diverting the first process gas from the first flow controller through a third flow controller to the process chamber or the exhaust, wherein the second flow controller is in fluid communication with the third flow controller; supplying a second process gas to the process chamber from a second gas panel through a second fast gas exchange module during a second process, comprises selectively diverting the second process gas from a fourth flow controller through a fifth flow controller to the process chamber or an exhaust, or selectively diverting the second process gas from the fourth flow controller through a sixth flow controller to the process chamber or the exhaust, wherein the fifth flow controller is in fluid communication with the sixth flow controller, wherein the first and second process gases are supplied into the process chamber in an alternating sequence; and synchronizing a change in a diverting state of each of the flow controllers in the first and second fast gas exchange modules so that a frequency of the first or second process gas flowing into the process chamber is twice a frequency of the change in the diverting state for each of the flow controllers in the first or second fast gas exchange module. 2. A method of supplying gases to a process chamber, comprising: supplying a first process gas to the process chamber from a first gas panel through a first fast gas exchange module during a first process, wherein the first fast gas exchange module comprising: a first flow controller coupling to the first gas panel; a second flow controller coupling to the first flow controller and the process chamber; and a third flow controller coupling to the second flow controller and the process chamber, wherein the first flow controller is operable to selectively divert the first process gas flowing from the first gas panel to the second flow controller or the third flow controller, the second flow controller is operable to selectively divert the first process gas flowing from the first flow controller to the processing chamber or a exhaust, and the third flow controller is operable to selectively divert the first process gas flowing from the second flow controller to the processing chamber or the exhaust; and supplying a second process gas to the processing chamber from a second gas panel through a second fast gas exchange module during a second process, wherein the second fast gas exchange module comprising: a fourth flow controller coupling to the second gas panel; a fifth flow controller coupling to the fourth flow controller and the process chamber; and a sixth flow controller coupling to the fifth flow controller and the process chamber, wherein the fourth flow controller is operable to selectively divert the second process gas flowing from the second gas panel to the fifth flow controller or the sixth flow controller, the fifth flow controller is operable to selectively divert the second process gas flowing from the fourth flow controller to the process chamber or the exhaust, and the sixth flow controller is operable to selectively divert the second process gas flowing from the fifth flow controller to the process chamber or the exhaust; and synchronizing a change in a diverting state of each of the flow controllers in the first and second fast gas exchange modules so that a frequency of the first or second process gas flowing into the process chamber is twice a frequency of the change in the diverting state for each of the flow controllers in the first or second fast gas exchange module. 3. The method of claim 2 , wherein the second and third flow controllers are controlled to simultaneously operate in a diverting state opposite to each other. 4. The method of claim 3 , wherein the first and second flow controllers simultaneously direct the first process gas from the first gas panel to the process chamber. 5. The method of claim 3 , wherein the first flow controller and the second flow controller simultaneously direct the first process gas from the first gas panel to the exhaust. 6. The method of claim 3 , wherein the first flow controller and the third flow controller simultaneously direct the first process gas from the first gas panel to the process chamber. 7. The method of claim 3 , wherein the first flow controller and the third flow controller simultaneously direct the first process gas from the first gas panel to the exhaust. 8. The method of claim 2 , wherein the fifth and sixth flow controllers are controlled to simultaneously operate in a diverting state opposite to each other. 9. The method of claim 8 , wherein the fourth and fifth flow controllers simultaneously direct the second process gas from the second gas panel to the process chamber. 10. The method of claim 8 , wherein the fourth flow controller and the fifth flow controller simultaneously direct the second process gas from the second gas panel to the exhaust. 11. The method of claim 8 , wherein the fourth flow controller and the sixth flow controller simultaneously direct the second process gas from the second gas panel to the process chamber. 12. The method of claim 8 , wherein the fourth flow controller and the sixth flow controller simultaneously direct the second process gas from the second gas panel to the exhaust. 13. The method of claim 2 , wherein the first and second process gases are selected from a group consisting of etching gas, deposition gas, passivation gas, and cleaning gas. 14. The method of claim 2 , wherein the first and second processes are performed in an alternating sequence. 15. A gas delivery system, comprising: a process chamber for processing a substrate; and a fast gas exchange module in fluid communication with a first gas panel and the process chamber, wherein the fast gas exchange module having a first flow controller configuration comprising: a first flow controller coupling to the first gas panel; a second flow controller coupling to the first flow controller and the process chamber; and a third flow controller coupling to the second flow controller and the process chamber, wherein the third flow controller comprises a first sub-flow controller, a second sub-flow controller, and a third sub-flow controller, the third sub-flow controller is not in fluid communication with the second sub-flow controller, and the first sub-flow controller and the second sub-flow controller or the first sub-flow controller and the third sub-flow controller are in fluid communication with each other and are operable to selectively divert a first gas flowing from the second flow controller to the process chamber or a exhaust; and wherein the second flow controller is in fluid communication with the third flow controller, wherein the first flow controller is operable to selectively divert the first gas flowing from the first gas panel to the second flow controller or the third flow controller, the second flow controller is operable to selectively divert the first gas flowing from the first flow controller to the third flow controller or to the process chamber. 16. The gas delivery system of claim 15 , wherein the second and third flow controllers are simultaneously operated in a diverting state opposite to eac