Aerosol exposure monitoring

What is claimed is: 1. An aerosol exposure monitor, comprising: an impactor; a sample chamber communicating with the impactor and defining a laminar fluid flow path along a first axis; a collection filter communicating with the sample chamber and removable from the aerosol exposure monitor; a pump communicating with the collection filter; a light source configured to generate a light beam that occupies a sensing volume in the sample chamber, wherein the fluid flow path passes through the sensing volume along the first axis, and the light beam propagates along a second axis that is at an angle to the first axis; a light detector; a first bore defining a first optical path from the light source to the sensing volume along the second axis; and a second bore defining a second optical path from the sensing volume to the light detector along a third axis, wherein the first axis, the second axis and the third axis are at angles to each other. 2. The aerosol exposure monitor of claim 1 , comprising at least one of the following: a sample inlet comprising an inlet opening configured such that the sample inlet establishes an inlet flow path that turns ninety degrees from the inlet opening to the impactor; a light trap disposed on a side of the sample chamber opposite to the first bore; an accelerometer configured for detecting motion of the aerosol exposure monitor along one or more axes; a differential pressure sensor configured for detecting a pressure drop across an orifice between the collection filter and the pump; a differential pressure sensor configured for detecting a pressure drop between an inlet side of the impactor and an outlet side of the collection filter. 3. The aerosol exposure monitor of claim 1 , wherein the impactor comprises a plurality of impactor stages, each successive impactor stage having a smaller cut-point than the other impactor stages. 4. The aerosol exposure monitor of claim 1 , wherein the sample chamber has a length between the impactor and the collection filter ranging from 20 mm to 22 mm, and a cross-sectional dimension ranging from 9 mm to 14.5 mm. 5. The aerosol exposure monitor of claim 1 , wherein the pump is configured for providing a flow rate ranging from 0.30 to 0.60 liters per minute. 6. The aerosol exposure monitor of claim 1 , wherein the light source is configured according to at least one of the following: the sensing volume is cylindrical; the sensing volume is cylindrical, and has a length ranging from 8.0 to 12.0 mm and a diameter ranging from 0.5 to 2.0 mm; the sensing volume is an elliptic cylinder. 7. The aerosol exposure monitor of claim 1 , wherein the light detector comprises a rectilinear sensing area communicating with the second bore. 8. The aerosol exposure monitor of claim 1 , comprising electronic circuitry configured according to at least one of the following: electronic circuitry configured for collecting quality control data during operation of the aerosol exposure monitor; electronic circuitry configured for collecting quality control data during operation of the aerosol exposure monitor, wherein the quality control data are selected from the group consisting of a flow rate of fluid through the collection filter, a pressure drop through the collection filter, a pressure drop from an inlet side of the impactor to an outlet side of the collection filter, a temperature of fluid flowing through the aerosol exposure monitor, a relative humidity of fluid flowing through the aerosol exposure monitor, data produced by an accelerometer of the aerosol exposure monitor defining wearing compliance, a voltage level of a battery of the aerosol exposure monitor, GPS data pertaining to a location of the aerosol exposure monitor, and a combination of two or more of the foregoing; electronic circuitry configured for adjusting the pump based on a parameter selected from the group consisting of a flow rate of fluid through the collection filter, a pressure drop across an orifice following the collection filter, a pressure drop from an inlet side of the impactor to an outlet side of the collection filter, a temperature of fluid flowing through the aerosol exposure monitor, a relative humidity of fluid flowing through the aerosol exposure monitor, and a combination of two or more of the foregoing. 9. The aerosol exposure monitor of claim 1 , comprising at least one of the following: a noise dampening device communicating with the pump; a noise dampening device communicating with the pump, wherein the noise dampening device comprises 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 collection filter and the pump inlet, and the outlet chamber communicates with the pump outlet. 10. A method for monitoring aerosol, the method comprising: sizing particles of the aerosol by flowing the aerosol through an impactor; collecting the sized particles by flowing the aerosol through a sample chamber along a first axis and through a collection filter, wherein the sized particles are collected on the collection filter, and wherein flowing the aerosol through the impactor, the sample chamber and the collection filter comprises operating a pump communicating with an outlet side of the collection filter; irradiating the sized particles flowing through the sample chamber by directing an irradiating light into the sample chamber along a second axis angled relative to the first axis, wherein the irradiating light establishes a sensing volume in the sample chamber, the aerosol flows through the sensing volume along the first axis, and scattered light propagates from the irradiated particles; directing the scattered light from the sensing volume to a light detector along a third axis angled relative to the first axis and the second axis to sense a total scattering potential of the sized particles; and a light source configured to generate a light beam that occupies a sensing volume in the sample chamber, wherein the fluid flow path passes through the sensing volume along the first axis, and the light beam propagates along a second axis that is at an angle to the first axis. 11. The method of claim 10 , comprising at least one of the following: wherein the flow of aerosol out from the impactor, through the sample chamber, and to the collection filter is substantially laminar; wherein the aerosol is flowed through the collection filter at a total system pressure drop through the collection filter of 2 inches H 2 O or less; wherein the aerosol is flowed through the collection filter at a flow rate ranging from 0.30 to 0.60 liters/min. 12. The method of claim 10 , wherein directing the irradiating light into the sample chamber comprises at least one of the following: establishing a cylindrical sensing volume of light in the sample chamber; establishing a cylindrical sensing volume of light in the sample chamber, and the cylindrical sensing volume has a length ranging from 8.0 to 12.0 mm and a cross-sectional dimension ranging from 0.5 to 2.0 mm; establishing a cylindrical sensing volume of light in the sample chamber, wherein the cylindrical sensing volume has an elliptical cross-section and the cross-sectional dimension is a major axis. 13. The method of claim 10 , wherein directing the scattered light to the light detector comprises directing the scattered light from the sample chamber as a beam having a rectilinear cross-section. 14. The method of claim 10 , comprising acquiring particle concentration data from the light detector, and sub