Analysis of the Anomalous Signals near the Tropopause before the Overshooting Convective System Onset over the Tibetan Plateau

Abstract EN

This study investigates the anomalous signals near the tropopause before the overshooting convective system (OCS) onset over the Tibetan Plateau (TP).

It is found that the tropopause height is stable at the maximum height for the 7th day and the 5th day before the OCS onset.

It then decreases significantly one day before and on the day of the OCS onset.

The upward motion in the troposphere is the strongest for the 5th day before the OCS onset.

From one day before and after the OCS onset, there are strong ascending motions at 500–300 hPa but weak descending motions near the tropopause.

It is proposed that the descending of the tropopause height on the day of the OCS onset is caused by frequent tropopause fold events over the eastern TP associated with frequent cold trough intrusion from the north and the southeastward movement of upper-level westerly jet stream.

The decrease of the tropopause height is accompanied by the intrusion of stratospheric air with higher potential vorticity (PV).

Positive potential vorticity anomalies on 350 K isentropic surface can be noted in the region where the tropopause height decreases one day before and on the day of the OCS onset.

With the deepening of the tropopause fold on the day of the OCS onset, there is not only downward motion near the tropopause in the area behind of the fold but also upward motion in the troposphere beneath the folding region.

In addition, the upward displacement of isentropic surfaces leads to an upper-level cold pool, which causes a reduction in static stability beneath the PV anomaly on the day of the OCS onset.

The upper-level PV anomalies and their associated strong instability in the middle troposphere can trigger convective activities by the release of potential instability on the day of the OCS onset.

The overshooting convection is more likely to occur due to lower tropopause height, although upward motion in the troposphere is not the strongest.