Microwave plasma reactors

What is claimed is: 1. A microwave plasma assisted reactor comprising: (a) a first microwave chamber having a reference plane at a reference axial location Zo and extending in an axial direction z>Zo, wherein the first microwave chamber comprises: (i) a first cylindrical waveguide section positioned adjacent the reference axial location Zo, extending in the axial direction z>Zo away from the reference axial location Zo, and having a radius of R 1 a; (ii) a second cylindrical waveguide section positioned adjacent the first cylindrical waveguide section, extending in the axial direction z>Zo away from the first cylindrical waveguide section, and having a radius of R 1 b such that R 1 b /R 1 a is greater than 1; and iii) an electromagnetic wave source; (b) a plasma chamber having an outer wall defining a cylindrical cross section with radius of R 2 , the plasma chamber extending into the first cylindrical waveguide section of the first microwave chamber such that at least a portion of the plasma chamber is located at z>Zo; (c) a conductive stage defining a cylindrical cross section with radius of R 3 and having a reference surface extending into the plasma chamber and defining a second microwave chamber in the plasma chamber (i) at z<Z.sub. 0 and (ii) between the plasma chamber outer wall and the conductive stage; and (d) a conducting short adjustably disposed in the second microwave chamber below Zo and in electrical contact with and movable with respect to the plasma chamber outer wall and the conductive stage, the axial distance between the conducting short and Zo being L 2 , and the axial distance between the conducting short and the reference surface of the conductive stage being L 1 ; wherein: R 3 /R 2 is 0.5 or less; and geometric scales of the reactor are configured such that, during operation of the reactor, electromagnetic fields are produced in the vicinity of Zo and in the plasma chamber, the electromagnetic fields comprising one or more of a TM 01 mode, a TEM 001 mode, and evanescent modes. 2. A reactor kit comprising a microwave plasma assisted reactor according to claim 1 , wherein the first microwave chamber comprises a plurality of separate, interconnected chamber sections each having a different radius and corresponding to a waveguide section of the first microwave chamber. 3. The microwave plasma assisted reactor of claim 1 , wherein R 3 /R 2 is in a range from 0.05 to 0.4. 4. The microwave plasma assisted reactor of claim 1 , wherein R 3 /R 2 is in a range from 0.05 to 0.3. 5. The microwave plasma assisted reactor of claim 1 , wherein L 2 and L 1 are capable of adjustment in the reactor by moving the conducting short. 6. The microwave plasma assisted reactor of claim 5 , wherein the conductive stage is movable such that both L 1 and L 2 are capable of independent adjustment during operation of the reactor by moving one or both of the conducting short and the conductive stage. 7. The microwave plasma assisted reactor of claim 1 , wherein the conducting short is slidable in an axial direction. 8. The microwave plasma assisted reactor of claim 7 , wherein the conductive stage is movable and slidable in the axial direction. 9. A process for depositing a component on a substrate, the process comprising: (a) providing a microwave plasma assisted reactor according to claim 1 , the reactor further comprising a deposition substrate mounted above an upper surface of the conductive stage; (b) operating the reactor at a pressure ranging from about 10 Torr to about 760 Torr to generate a plasma discharge in the plasma chamber; and (c) depositing a component on the substrate. 10. The process of claim 9 , wherein: (i) operating the reactor comprises feeding a source gas comprising a hydrogen source gas and a methane source gas to the plasma chamber; and (ii) the component is selected from the group consisting of single-crystal diamond, microcrystalline polycrystalline diamond, nanocrystalline polycrystalline diamond, and combinations thereof. 11. The process of claim 9 , wherein, during parts (b) and (c) of operating the reactor and depositing the component on the substrate, electromagnetic fields are produced in the vicinity of Z 0 and the deposition substrate in the plasma chamber, the electromagnetic fields comprising one or more of a TM 01 mode, a TEM 001 mode, and evanescent modes.