Processes Shaping the Frontal-Scale Time-Mean Surface Wind Convergence Patterns around the Kuroshio Extension in Winter

• Published in: Journal of climate Vol. 33; no. 1; pp. 3 - 25
• Main Authors: Masunaga, Ryusuke, Nakamura, Hisashi, Taguchi, Bunmei, Miyasaka, Takafumi
• Format: Journal Article
• Language: English
• Published: Boston American Meteorological Society 01.01.2020
• Subjects: Ascent; Atmospheric boundary layer; Atmospheric processes; Atmospheric structure; Boundary currents; Climate; Cluster analysis; Cold front; Cold fronts; Computer simulation; Convective precipitation; Convergence; Convergence and divergence; Cyclones; Divergence; Fronts; Heat; Heating; New products; Numerical simulations; Ocean currents; Precipitation; Remote sensing systems; Satellite observation; Sea currents; Sea surface; Sea surface temperature; SPECIAL Climate and Frontal Air-Sea Interaction COLLECTION; Surface temperature; Surface wind; Western boundary currents; Wind; Winter
• ISSN: 0894-8755; 1520-0442
• DOI: 10.1175/jcli-d-19-0097.1

High-resolution satellite observations and numerical simulations have revealed that climatological-mean surface wind convergence and precipitation are enhanced locally around the midlatitude warm western boundary currents (WBCs) with divergence slightly to their poleward side. While steep sea surface temperature (SST) fronts along the WBCs have been believed to play an important role in shaping those frontal-scale atmospheric structures, the mechanisms and processes involved are still under debate. The present study explores specific daily scale atmospheric processes that are essential for shaping the frontal-scale atmospheric structure around the Kuroshio Extension (KE) in winter, taking advantage of a new product of global atmospheric reanalysis. Cluster analysis and case studies reveal that a zonally extending narrow band of surface wind convergence frequently emerges along the KE, which is typically observed under the surface northerlies after the passage of a developed synoptic-scale cyclone. Unlike its counterpart around the cyclone center and associated cold front, the surface convergence tends to be in moderate strength and more persistent, contributing dominantly to the distinct time-mean convergence/divergence contrast across the SST front. Accompanying ascent and convective precipitation, the band of convergence is a manifestation of a weak stationary atmospheric front anchored along the SST front or generation of a weak meso-α-scale cyclone. By reinforcing the ascent and convergence, latent heating through convective processes induced by surface convergence plays an important role in shaping the frontal-scale atmospheric structure around the KE.