Numerical Study of Explosively Developing Extratropical Cyclones in the Northwestern Pacific Region

• Published in: Monthly weather review Vol. 136; no. 2; pp. 712 - 740
• Main Authors: KUWANO-YOSHIDA, Akira, ASUMA, Yoshio
• Format: Journal Article
• Language: English
• Published: Boston, MA American Meteorological Society 01.02.2008
• Subjects: Atmospheric research; Cyclones; Earth, ocean, space; Exact sciences and technology; External geophysics; Growth rate; Heat transfer; Ice; Latent heat; Mathematical models; Meteorology; Radar systems; Research methodology; Science; Water vapor; Wind shear; Okhotsk Sea; West Pacific; United States; Pacific Ocean; Northwest Pacific; Japan Sea; North Pacific; Pennsylvania; Pacific region; INW, Japan Sea; INW, Okhotsk Sea; short period waves; High altitude; Extratropical cyclone; Propagation velocity; Atmosphere model; atmospheric precipitation; sensitivity analysis; Regional scope; digital simulation; North America; Cold front; Cyclogenesis; Heat liberation; Mesoscale; extreme value; water vapor; Jet (atmosphere, ocean); condensation; Jet stream; latent heat
• ISSN: 0027-0644; 1520-0493
• DOI: 10.1175/2007mwr2111.1

Abstract Numerical simulations of six explosively developing extratropical cyclones in the northwestern Pacific Ocean region are conducted using a regional mesoscale numerical model [the fifth-generation Pennsylvania State University–National Center for Atmospheric Research Mesoscale Model (MM5)]. Cyclones are categorized according to the locations where they form and develop: Okhotsk–Japan Sea (OJ) cyclones originate over the eastern Asian continent and develop over the Sea of Japan or the Sea of Okhotsk, Pacific Ocean–land (PO–L) cyclones also form over the Asian continent and develop over the northwestern Pacific Ocean, and Pacific Ocean–ocean (PO–O) cyclones form and develop over the northwestern Pacific Ocean. Two cases (the most extreme and normal deepening rate cases for each cyclone type) are selected and simulated. Simulations show that the extreme cyclone of each type is characterized by a different mesoscale structure and evolutionary path, which strongly reflect the larger-scale environment: an OJ cyclone has the smallest deepening rates, associated with a distinct upper-level shortwave trough, a clear lower-level cold front, and a precipitation area that is far from the cyclone center; a PO–L cyclone has moderate deepening rates with high propagation speeds under zonally stretched upper-level jets; and a PO–O cyclone has the strongest deepening rates associated with large amounts of precipitation near its center. Sensitivity experiments involving the latent heat release associated with water vapor condensation show that PO–O cyclones rarely develop without a release of latent heat and their structures are drastically different from the control runs, while OJ cyclones exhibit almost the same developments and have similar structures to the control runs. These tendencies can be seen in both extreme and normal deepening rate cases. These results reveal that the importance of latent heat release to explosive cyclone development varies among the cyclone types, as is reflected by the cyclone origin, frontal structure, moisture distribution, and jet stream configuration.