Synthetic jets in compressors

What is claimed is: 1. A stationary vane for a turbo-machine, the stationary vane comprising: an airfoil including a leading edge, a trailing edge, and a fluid stream interfacing surface extending between the leading edge and the trailing edge; a synthetic jet including a backside cavity, a jet cavity including a frontside cavity adjoining the backside cavity, and a jet passage extending from the fluid stream interfacing surface towards the frontside cavity, the jet passage being in flow communication with the frontside cavity; and a disk located between the backside cavity and the frontside cavity, the disk including a cylindrical disk with a cylindrical shape, and a coating on each side of the cylindrical disk, the coating being a piezo electric ceramic material; and wherein the airfoil includes a first body portion including the leading edge, the trailing edge, and the jet cavity; and a second body portion including a portion of the fluid stream interfacing surface and the backside cavity, the second body portion being affixed to the first body portion securing the disk between the backside cavity and the frontside cavity. 2. The stationary vane of claim 1 , wherein the jet cavity is configured to have a Helmholtz frequency within 200 Hertz of a resonant frequency of the disk. 3. The stationary vane of claim 2 , wherein the resonant frequency of the disk is from 1150 Hertz to 1250 Hertz. 4. The stationary vane of claim 1 , wherein the fluid stream interfacing surface is on a pressure side of the airfoil. 5. The stationary vane of claim 4 , wherein the jet passage is located adjacent the trailing edge and is configured to inject a fluid perpendicular to the fluid stream interfacing surface. 6. The stationary vane of claim 1 , wherein the jet cavity includes a static volume from 4.11 cm 3 to 4.47 cm 3 . 7. A synthetic jet for a turbo-machine including a fluid stream interfacing structure with a fluid stream interfacing surface, the synthetic jet comprising: a disk including a cylindrical disk including a cylindrical shape and a diameter from 40.8 millimeters to 41.2 millimeters, and a coating located on each side of the cylindrical disk, the coating being a piezo electric ceramic material; a backside cavity located in the fluid stream interfacing structure; and a jet cavity configured to have a Helmholtz frequency within twenty percent of a resonant frequency of the disk located in the fluid stream interfacing structure, the jet cavity including a frontside cavity adjoining the backside cavity, the frontside cavity being separated from the backside cavity by the disk, a cavity passage extending from the frontside cavity towards the fluid stream interfacing surface, and a jet passage extending from the fluid stream interfacing surface to the cavity passage, the jet passage being in flow communication with the frontside cavity; and wherein the backside cavity includes a conical shape with a rounded apex and a second diameter at a base of the conical shape, and the frontside cavity includes a second cylindrical shape with a third diameter. 8. The synthetic jet of claim 7 , wherein the resonant frequency of the disk is from 1150 Hertz to 1250 Hertz. 9. The synthetic jet of claim 8 , wherein the Helmholtz frequency of the jet cavity is within 200 Hertz of the resonant frequency. 10. The synthetic jet of claim 7 , wherein the coating on each side of the cylindrical disk includes a second diameter from 28.0 millimeters to 28.4 millimeters and a thickness from 0.1778 millimeters to 0.2032 millimeters. 11. The synthetic jet of claim 7 , wherein the cylindrical disk includes brass. 12. The synthetic jet of claim 7 , wherein the jet passage is angled perpendicular to a portion of the fluid stream interfacing surface adjacent the jet passage. 13. A compressor, comprising: a shaft; an impeller mounted to the shaft; and a stationary vane assembly including a plate portion with an annular shape, the plate portion including a first base surface, a second base surface opposite the first base surface, an outer edge, an inner edge located inward from the outer edge, and a plurality of cover cavities extending from the second base surface towards the first base surface, a plurality of covers, each cover of the plurality of covers located in one of the plurality of cover cavities, a plurality of airfoils extending from the first base surface in the direction opposite the second base surface, each airfoil of the plurality of airfoils including a leading edge adjacent the inner edge, a trailing edge adjacent the outer edge, and a fluid stream interfacing surface extending between the leading edge and the trailing edge, and a plurality of synthetic jets, each synthetic jet of the plurality of synthetic jets including a backside cavity located within one of the plurality of covers, a jet cavity including a frontside cavity in the plate portion adjoining the backside cavity, a cavity passage extending from the frontside cavity into one of the plurality of airfoils, and a jet passage extending from the cavity passage to the fluid stream interfacing surface, and a disk between the backside cavity and the frontside cavity, the disk including a cylindrical disk with a cylindrical shape, and a coating on each side of the cylindrical disk, the coating being a piezo electric ceramic material. 14. The compressor of claim 13 , wherein the jet passage is a slot. 15. The compressor of claim 13 , wherein the jet passage is configured to inject a fluid from 0 degrees to 7 degrees relative to a tangential direction of the fluid stream interfacing surface towards the trailing edge. 16. The compressor of claim 13 , wherein the fluid stream interfacing surface is in a suction side of the airfoil. 17. The compressor of claim 13 , wherein the disk includes a resonant frequency from 1150 to 1250 Hertz and the jet cavity is configured to have a Helmholtz frequency within 200 Hertz of the resonant frequency of the disk. 18. The compressor of claim 13 , wherein the jet cavity includes a static volume from 4.592 cm 3 to 4.920 cm 3 .