After-treatment system

We claim: 1. An after-treatment system for use in a machine having an engine, the engine having an exhaust conduit, the exhaust conduit adapted to route a flow of exhaust gas from the engine during operation of the engine, the after-treatment system being adapted for connection to the exhaust conduit and disposed to receive and treat the flow of exhaust gas from the engine, the after-treatment system comprising: a diesel oxidation catalyst (DOC) connected to the exhaust conduit and arranged to receive the flow of exhaust gas from the engine; a transfer conduit connected to a downstream end of the DOC; a diesel exhaust fluid (DEF) delivery device fluidly coupled to the transfer conduit and adapted to selectively inject DEF into the transfer conduit to be carried in a downstream direction by gas passing through the transfer conduit during operation; a soot-reducing device connected to a downstream end of the transfer conduit, the soot-reducing device being arranged to receive the gas passing through the transfer conduit during operation; and a selective catalytic reduction (SCR) catalyst connected to a downstream end of the soot-reducing device opposite the transfer conduit, the SCR catalyst being arranged to receive the gas passing through the soot-reducing device during operation, wherein each of the DOC, the soot-reducing device, and the SCR catalyst has a generally cylindrical shape, and wherein a diameter of the DOC is smaller than a diameter of the soot-reducing device and smaller than a diameter of the SCR catalyst. 2. The after-treatment system of claim 1 , wherein the soot-reducing device is an uncatalyzed soot-reducing device. 3. The after-treatment system of claim 1 , wherein the soot-reducing device includes a hydrolysis catalyst. 4. The after-treatment system of claim 1 , wherein the soot-reducing device is a diesel particulate filter (DPF) that is made from a monolithic, thin wall-flow type substrate. 5. The after-treatment system of claim 4 , wherein the DPF is made from advanced cordierite (AC) or aluminum titanate (AT). 6. The after-treatment system of claim 5 , wherein the DPF has an asymmetric channel (ACT) construction such that a size of inlet channels of the DPF is larger than a size of outlet channels of the DPF. 7. The after-treatment system of claim 4 , wherein the DPF has about 300 channels per square inch (cpsi). 8. The after-treatment system of claim 1 , wherein the SCR catalyst further includes an ammonia oxidation catalyst (AMOx). 9. The after-treatment system of claim 8 , wherein the AMOx catalyst is formed as a coating on the SCR catalyst. 10. The after-treatment system of claim 1 , wherein the SCR catalyst is built on a substrate having about 600 cpsi. 11. The after-treatment system of claim 1 , wherein a substrate of the SCR catalyst and a substrate of the soot-reducing device are each enclosed in a common housing. 12. The after-treatment system of claim 1 , wherein the after-treatment is configured to remove more than 98% of soot on a mass or particulate count basis, and to reduce NOx by more than 96% on a mass basis, from the flow of exhaust gas from the engine. 13. The after-treatment system of claim 1 , wherein a ratio of the diameter of the DOC to the diameter of the soot-reducing device is less than about 2/3. 14. The after-treatment system of claim 1 , wherein the diameter of the soot-reducing device is equal to the diameter of the SCR catalyst. 15. The after-treatment system of claim 1 , wherein the DOC further includes structures arranged to absorb NOx from the flow of exhaust gas from the engine. 16. The after-treatment system of claim 1 , wherein the DOC, the transfer conduit, the soot-reducing device, and the SCR catalyst are arranged fluidly in series within the after-treatment system, the DOC being located upstream of the transfer conduit along a flow direction through the after-treatment system, the transfer conduit being located upstream of the soot-reducing device along the flow direction through the after-treatment system, and the soot-reducing device being located upstream of the SCR catalyst along the flow direction through the after-treatment system, the flow direction through the after-treatment system fluidly extending from the DOC toward the SCR catalyst. 17. The after-treatment system of claim 1 , wherein the DOC is mounted closer to the engine than to the soot-reducing device. 18. The after-treatment system of claim 1 , wherein the soot-reducing device is a diesel particulate filter (DPF) that is configured for passive regeneration at a temperature of about 200 deg. C. 19. The after-treatment system of claim 1 , further comprising an active regeneration device disposed in fluid communication with the soot-reducing device at a location upstream of the soot-reducing device, the active regeneration device being configured to increase a temperature of the flow of exhaust upstream of the soot-reducing device. 20. The after-treatment system of claim 11 , wherein the substrate of the SCR catalyst and the substrate of the soot-reducing device are the only exhaust after-treatment substrates disposed within the common housing.