Assessing wellbore characteristics using high frequency tube waves

What is claimed is: 1. A hydrocarbon well, comprising: a wellbore comprising a surface casing string that couples the wellbore to a wellhead located at a surface and a production casing string that extends through a reservoir within a subsurface, wherein a fluid column is present within the wellbore; a high-frequency tube wave generator that is hydraulically coupled to the wellbore and is configured to generate high-frequency tube waves that propagate within the fluid column, wherein the high-frequency tube waves comprise a selected waveform containing a specific bandwidth of high-frequency components, and wherein the specific bandwidth of high-frequency components comprises at least 10% of frequencies above 1,000 Hertz (Hz); and a receiver that is hydraulically coupled to the wellbore and is configured to record data corresponding to the generated high-frequency tube waves and reflected high-frequency tube waves propagating within the fluid column, wherein the data relate to characteristics of the wellbore. 2. The hydrocarbon well of claim 1 , wherein the characteristics of the wellbore comprise characteristics relating to reflectors within the wellbore, and wherein the reflectors comprise acoustic impedance boundaries arising from changes in cross-sectional area within the wellbore or changes in acoustic wave speeds of the high-frequency tube waves propagating within the fluid column. 3. The hydrocarbon well of claim 2 , wherein the reflectors comprise at least one of one or more casing joints, one or more liner hangers, one or more valves, one or more plugs, one or more sand bridges, or fractures corresponding to one or more perforation clusters within a particular stage of the hydrocarbon well. 4. The hydrocarbon well of claim 1 , wherein the high-frequency tube wave generator is configured to generate the high-frequency tube waves when the fluid column within the wellbore is static. 5. The hydrocarbon well of claim 1 , wherein the fluid column comprises fracturing fluid that is present within the wellbore during a hydraulic fracturing process, and wherein the production casing string comprises a plurality of stages that are created during the hydraulic fracturing process, and wherein each of the plurality of stages comprises perforation clusters and corresponding fractures extending into the reservoir. 6. The hydrocarbon well of claim 5 , wherein the high-frequency tube wave generator is configured to generate the high-frequency tube waves after each of the plurality of stages is hydraulically fractured, and wherein the data recorded by the receiver relate to characteristics of the fractures corresponding to the perforation clusters within each of the plurality of stages. 7. The hydrocarbon well of claim 6 , wherein the characteristics of the fractures corresponding to the perforation clusters comprise at least one of a number of perforation clusters for which fractures have formed, sizes of the fractures corresponding to the perforation clusters for which the fractures have formed, locations of the perforation clusters for which the fractures have formed, or a number of perforation clusters that have been stimulated to at least a threshold level as measured by the characteristics of the fractures corresponding to the perforation clusters. 8. The hydrocarbon well of claim 6 , wherein the high-frequency tube wave generator is further configured to generate the high-frequency tube waves before each of the plurality of stages is hydraulically fractured, and wherein the data recorded by the receiver forms a baseline pressure response for each of the plurality of stages. 9. The hydrocarbon well of claim 5 , wherein at least one of the high-frequency tube wave generator and the receiver are positioned within the wellbore in proximity to the perforation clusters. 10. The hydrocarbon well of claim 1 , wherein the receiver and the high-frequency tube wave generator are located at a predetermined minimum distance from each other to prevent interference between the generated high-frequency tubes and the reflected high-frequency tube waves propagating within the fluid column. 11. The hydrocarbon well of claim 1 , wherein at least one of the high-frequency tube wave generator or the receiver is connected directly to the wellhead via one or more tubings. 12. The hydrocarbon well of claim 1 , wherein at least one of the high-frequency tube wave generator or the receiver is located at one or more locations within the wellbore. 13. The hydrocarbon well of claim 1 , wherein the high-frequency tube wave generator comprises at least one high-speed, actuated valve that is electrically or hydraulically controlled. 14. The hydrocarbon well of claim 13 , wherein the at least one high-speed, actuated valve is configured to generate the high-frequency tube waves by: opening and closing in a highly-controllable, highly-repeatable manner to allow a portion of a fluid within the fluid column to bleed off to open air or a storage container; or opening and closing in a highly-controllable, highly-repeatable manner to inject a fluid into the fluid column within the wellbore. 15. The hydrocarbon well of claim 13 , wherein the at least one high-speed, actuated valve comprises two or more high-speed, actuated valves connected in parallel or in series, and wherein the two or more high-speed, actuated valves are electrically synchronized to open and close in a predetermined sequence and with a predetermined number of cycles to generate the high-frequency tube waves with the selected waveform. 16. The hydrocarbon well of claim 1 , wherein the high-frequency tube wave generator comprises one or more rupture disks coupled with one or more corresponding valves, and wherein the one or more rupture disks and the one or more corresponding valves are configured to generate the high-frequency tube waves via failure of the one or more rupture disks and quick closure of the one or more corresponding valves in a highly-controllable, highly-repeatable manner to allow a portion of a fluid within the fluid column to bleed off to open air or a storage container. 17. The hydrocarbon well of claim 1 , wherein the high-frequency tube wave generator comprises a fast-acting valve and a pipe that is hydraulically connected to the wellhead via the fast-acting valve, and wherein the fast-acting valve and the pipe are configured to generate the high-frequency tube waves via opening of the fast-acting valve to allow pressurized fluid within fluid column to oscillate between an entrance and a tip of the short pipe. 18. The hydrocarbon well of claim 1 , wherein the high-frequency tube wave generator comprises a piezoelectric crystal-based source that is deployed within the production casing string and is configured to generate high-frequency tube waves with narrow frequency components. 19. The hydrocarbon well of claim 1 , wherein the high-frequency tube wave generator comprises an explosive shock pulse generator. 20. The hydrocarbon well of claim 1 , wherein the specific bandwidth of high-frequency components comprises an upper frequency limit that is selected based on an expected attenuation of the high-frequency tube waves and a minimum wavelength that can be tolerated for the high-frequency tube waves.