Gas processing device with noise dampening

What is claimed is: 1. A gas processing device, comprising: a housing; a sample inlet defining a gas flow path into the housing; a pump disposed in the housing and comprising a pump inlet and a pump outlet; and a noise dampening device disposed in the housing and comprising an inlet chamber, an outlet chamber, and an elastomeric membrane interposed between and fluidly isolating the inlet chamber and the outlet chamber, wherein the inlet chamber is interposed between the sample inlet and the pump inlet, and the outlet chamber communicates with the pump outlet, such that the gas flow path runs through inlet chamber into the pump, and through the pump into the outlet chamber. 2. The gas processing device of claim 1 , wherein the noise dampening device comprises an exhaust tube communicating with the outlet chamber, and the outlet chamber is interposed between the pump outlet and the exhaust tube. 3. The gas processing device of claim 2 , wherein the exhaust tube has a length ranging from 1 to 15 cm. 4. The gas processing device of claim 2 , wherein the exhaust tube terminates in an interior of the housing. 5. The gas processing device of claim 1 , wherein the inlet chamber comprises a first port communicating with the sample inlet and a second port communicating with the pump inlet, and the outlet chamber comprises a third port communicating with the pump outlet and a fourth port communicating with a region outside the noise dampening device. 6. The gas processing device of claim 5 , wherein the first port, the second port, the third port and the fourth port are arranged such that gas flow through the inlet chamber is counter to gas flow through the outlet chamber. 7. The gas processing device of claim 5 , wherein the first port and the second port are oriented at an angle to each other such that the inlet chamber establishes a gas flow path that includes a change in direction, and the third port and the fourth port are oriented at an angle to each other such that the outlet chamber establishes a gas flow path that includes a change in direction. 8. The gas processing device of claim 1 , comprising a sensor communicating with an interior of the noise dampening device and configured to measure a property of gas flowing through the noise dampening device. 9. The gas processing device of claim 8 , wherein the sensor comprises a temperature sensor, a relative humidity sensor, or both a temperature sensor and a relative humidity sensor. 10. The gas processing device of claim 1 , wherein the noise dampening device comprises a fluid filter spanning a cross-sectional flow area of the inlet chamber, the outlet chamber, or both the inlet chamber and the outlet chamber. 11. The gas processing device of claim 10 , wherein the fluid filter comprises an open-cell foam. 12. The gas processing device of claim 1 , comprising a collection filter between the sample inlet and the inlet chamber. 13. The gas processing device of claim 1 , comprising a sample chamber between the sample inlet and the inlet chamber, a light source communicating with the sample chamber, and a light detector communicating with the sample chamber. 14. The gas processing device of claim 1 , comprising an impactor between the sample inlet and the collection filter. 15. A method for monitoring aerosol, the method comprising: operating a pump to establish a flow of aerosol into a housing and to a collection filter disposed in the housing, wherein aerosol particles of a desired size range are collected on the collection filter and gas from the aerosol flows through the collection filter; flowing the gas from an outlet side of the collection filter, through an inlet chamber, and into an inlet of the pump; and flowing the gas from an outlet of the pump, through an outlet chamber, and through an exhaust port open to a region outside the outlet chamber, wherein the outlet chamber is adjacent to the inlet chamber and an elastomeric membrane is interposed between and fluidly isolates the inlet chamber and the outlet chamber, wherein the gas flowing through the inlet chamber contacts a first side of the elastomeric membrane, and the gas flowing through the outlet chamber simultaneously contacts a second side of the elastomeric membrane, and noise associated with the respective flows of the gas through the inlet chamber and the outlet chamber is reduced. 16. The method of claim 15 , comprising flowing the gas through an exhaust tube connected to the exhaust port, wherein the exhaust tube has a length ranging from 1.0 to 15.0 cm. 17. The method of claim 15 , wherein the gas flows through the inlet chamber in a direction opposite to the gas flowing through the outlet chamber. 18. The method of claim 15 , wherein the gas flows into the inlet chamber through a first port, out from the inlet chamber through a second port, into the outlet chamber through a third port and out from the inlet chamber through the exhaust port, the flow of gas through the inlet chamber changes direction between the first port and the second port, and the flow of gas through the outlet chamber changes direction between the third port and the fourth port. 19. The method of claim 15 , comprising sensing a property of the gas flowing through the inlet chamber or the outlet chamber. 20. The method of claim 19 , wherein the property sensed is temperature, relative humidity, or both temperature and relative humidity. 21. The method of claim 15 , comprising flowing the gas through an open cell filter in the inlet chamber, in the outlet chamber, or in both the inlet chamber and the outlet chamber.