Treating sulfur dioxide containing stream by acid aqueous absorption

What is claimed is: 1. A method for treating a tail gas of a Claus process to remove sulfur-containing compounds, the method comprising: combusting a tail gas of a Claus process in an excess of oxygen gas, wherein the excess of oxygen gas comprises a number of moles of oxygen exceeding the number of moles of oxygen required to fully combust the sulfur-containing compounds, to yield a thermal oxidizer effluent, wherein the thermal oxidizer effluent comprises sulfur dioxide, water vapor, and oxygen; cooling the thermal oxidizer effluent to yield a cooled thermal oxidizer effluent; flowing the cooled thermal oxidizer effluent to a quench tower; contacting the cooled thermal oxidizer effluent in the quench tower with a dilute aqueous acid quench stream to condense water vapor and dissolve the sulfur dioxide to yield sulfurous acid, hydrated sulfur dioxide, or a combination of sulfurous acid and hydrated sulfur dioxide; oxidizing the sulfurous acid or hydrated sulfur dioxide with oxygen from the thermal oxidizer effluent to yield a produced dilute aqueous acid stream that comprises sulfuric acid; cooling the produced dilute aqueous acid stream to yield a cooled dilute aqueous acid stream; splitting the cooled dilute aqueous acid stream into the dilute aqueous acid quench stream and a dilute aqueous acid buffer stream; and flowing the dilute aqueous acid quench stream to the quench tower. 2. The method of claim 1 , further comprising flowing the dilute aqueous acid buffer stream to a water treatment unit, wherein the water treatment unit yields a permeate that is substantially water and a retentate that is concentrated sulfuric acid. 3. The method of claim 2 , further comprising: contacting the sulfur dioxide with a fresh water stream; oxidizing sulfurous acid, hydrated sulfur dioxide, or both into sulfuric acid with the excess of oxygen in the thermal oxidizer effluent; recovering a portion of the fresh water stream; monitoring the pH of the recovered water; and in response to a pH of the recovered water that is less than 0.5, flowing the recovered water to the water treatment unit. 4. The method of claim 3 , further comprising flowing the permeate of the water treatment unit to the quench tower as the fresh water stream. 5. The method of claim 2 , wherein the retentate of the water treatment unit is flowed to a sulfur recovery unit to enrich a Claus furnace in oxygen. 6. The method of claim 1 , wherein contacting the cooled thermal oxidizer effluent in the quench tower with a dilute aqueous acid quench stream to condense water vapor and dissolve the sulfur dioxide to yield a produced dilute aqueous acid stream that comprises sulfurous acid, hydrated sulfur dioxide, or a combination of sulfurous acid and hydrated sulfur dioxide yields a produced dilute aqueous acid stream that comprises between about 2 and about 20 wt % sulfuric acid. 7. The method of claim 1 , wherein splitting the cooled dilute aqueous acid stream into the dilute aqueous acid quench stream and the dilute aqueous acid buffer stream comprises splitting the cooled dilute aqueous acid stream into the dilute aqueous acid quench stream and a dilute aqueous acid buffer stream, wherein the dilute aqueous acid buffer stream comprises approximately the same volume as the water condensed from the thermal oxidizer effluent. 8. The method of claim 1 , wherein splitting the cooled dilute aqueous acid stream into the dilute aqueous acid quench stream and a dilute aqueous acid buffer stream comprises splitting the cooled dilute aqueous acid stream evenly, wherein the dilute aqueous acid quench stream and the dilute aqueous acid buffer stream each comprise approximately 50% of the cooled dilute aqueous acid stream. 9. A system for removing sulfur-containing compounds from a gas, the system comprising: a thermal oxidizer configured to receive a gas comprising sulfur-containing compounds and to combust the sulfur-containing compounds in an excess of oxygen gas, wherein the excess of oxygen gas comprises a number of moles of oxygen exceeding the number of moles of oxygen required to fully combust the sulfur-containing compounds, to yield a thermal oxidizer effluent that contains sulfur dioxide; a waste heat recovery system coupled to the thermal oxidizer and configured to cool the thermal oxidizer effluent to yield a cooled thermal oxidizer effluent; a quench tower coupled to the waste heat recovery system and configured to receive the cooled thermal oxidizer effluent, and contact the cooled thermal oxidizer effluent with a dilute aqueous acid quench stream to dissolve the sulfur dioxide to sulfurous acid, hydrated sulfur dioxide, or a combination of sulfurous acid and hydrated sulfur dioxide, oxidize the sulfurous acid, hydrated sulfur dioxide, or both to sulfuric acid, and yield a produced dilute aqueous acid stream comprising sulfuric acid; and a cooler system coupled to the quench tower, wherein the quench tower is configured to flow the produced dilute aqueous acid stream to the cooler system, and wherein the cooler system is configured to: receive the produced dilute aqueous acid stream, cool the produced dilute aqueous acid stream to yield a cooled dilute aqueous acid stream, split the cooled dilute aqueous acid stream into the dilute aqueous acid quench stream and a dilute aqueous acid buffer stream; and flow the dilute aqueous acid quench stream to the quench tower. 10. The system of claim 9 , further comprising a water treatment unit, wherein the water treatment unit is coupled to the cooler system and configured to receive the dilute aqueous acid buffer stream from the cooler system, and wherein the water treatment unit is configured to yield a permeate stream that is substantially water and a retentate stream that is concentrated sulfuric acid. 11. The system of claim 10 , further comprising a buffer tank coupled between the cooler system and the water treatment unit, wherein the buffer tank is configured to receive the dilute aqueous acid buffer stream and to flow the dilute aqueous acid buffer stream to the water treatment unit. 12. The system of claim 11 , wherein the buffer tank further comprises a vent, wherein the vent is coupled to the quench tower and configured to flow undissolved gases to the quench tower. 13. The system of claim 11 , wherein the quench tower comprises: an upper section; a mid-section; and a lower section, wherein the upper section and the lower section are connected in the mid-section by a plate, wherein the plate comprises bubble caps, wherein the plate is configured to collect liquid and allow gas to pass through the plate. 14. The system of claim 13 , further comprising: a second buffer tank coupled between the quench tower and a second cooler, wherein the second buffer tank is configured to receive recovered water from the quench tower, and wherein the second buffer tank comprises a second vent, and the second vent is coupled to the quench tower and configured to flow undissolved gases to the quench tower; a fresh water stream, wherein the fresh water stream enters the quench tower at the upper section of the quench tower, and wherein the plate is configured to recover fresh water and flow the recovered water to the second buffer tank; a second cooler, wherein the second cooler is configured to cool the recovered water from the second buffer tank and flow the cooled recovered water to the quench tower as the fresh water stream; and a pH monitor configured to monitor the pH of the recovered water, wherein the second buffer tank is configured to flow the recovered water to the buffer tank via a valve when the pH