Abstract
Abstract. How orographic mixed-phase clouds respond to the change in cloud condensation nuclei (CCN) and ice nucleating particles (INPs) are highly uncertain. The main snow production mechanism in warm and cold mixed-phase orographic clouds (referred to as WMOCs and CMOCs, respectively, distinguished here as those having cloud tops warmer and colder than −20 °C) could be very different. We quantify the CCN and INP impacts on supercooled water content, cloud phases, and precipitation for a WMOC case and a CMOC case, with sensitivity tests using the same CCN and INP concentrations between the WMOC and CMOC cases. It was found that deposition plays a more important role than riming for forming snow in the CMOC case, while the role of riming is dominant in the WMOC case. As expected, adding CCN suppresses precipitation, especially in WMOCs and low INPs. However, this reverses strongly for CCN of 1000 cm−3 and larger. We found a new mechanism through which CCN can invigorate mixed-phase clouds over the Sierra Nevada and drastically intensify snow precipitation when CCN concentrations are high (1000 cm−3 or higher). In this situation, more widespread shallow clouds with a greater amount of cloud water form in the Central Valley and foothills west of the mountain range. The increased latent heat release associated with the formation of these clouds strengthens the local transport of moisture to the windward slope, invigorating mixed-phase clouds over the mountains, and thereby producing higher amounts of snow precipitation. Under all CCN conditions, increasing the INPs leads to decreased riming and mixed-phase fraction in the CMOC as a result of liquid-limited conditions, but has the opposite effects in the WMOC as a result of ice-limited conditions. However, precipitation in both cases is increased by increasing INPs due to an increase in deposition for the CMOC but enhanced riming and deposition in the WMOC. Increasing the INPs dramatically reduces supercooled water content and increases the cloud glaciation temperature, while increasing CCN has the opposite effect with much smaller significance.
Highlights
Snowpack in the Sierra Nevada is California’s largest source of fresh water
Results regarding the cloud condensation nuclei (CCN) and ice nucleating particles (INPs) impact on supercooled water content in the warm mixed-phase orographic clouds (WMOCs) case are similar to those in the cold mixed-phase orographic clouds (CMOCs) case: increasing the INPs dramatically reduces SCW and increases cloud glaciation temperature, while increasing CCN has the opposite effect with much smaller significance (Fig. 12b)
Note that INP effects are more significant at higher INP concentrations in this case, while in the CMOC the sensitivity decreases as INP increases, suggesting that the optimal INP concentration for the maximum INP impact is higher in warmer clouds than colder clouds because ice formation at warmer cloud temperatures is less efficient
Summary
Snowpack in the Sierra Nevada is California’s largest source of fresh water. Understanding the factors contributing to snow precipitation over the mountains has important implications for predicting the hydrology and local climate of the western US. This has motivated a series of CalWater field campaigns carried out since 2009 to improve understanding of processes influencing precipitation and water supply in California (Ralph et al, 2016). Linked to precipitation is the distribution of cloud liquid and ice phases, which may be influenced by supercooled liquid commonly occurring in orographic clouds over the Sierra Nevada (Rosenfeld et al, 2013).
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