New research reveals Pele is powerful, even in the skyUniversity of Hawaiʻi at Mānoa
Professor, Atmospheric Science, School of Ocean and Earth Science and Technology
Andre Pattantyus, (845) 264-3582
Graduate Assistant, School of Ocean and Earth Science and Technology
One might assume that a tropical storm moving through volcanic smog (vog) would sweep up the tainted air and march on, unchanged. However, a recent study from atmospheric scientists at the University of Hawai‘i at Mānoa (UHM) revealed that although they are microscopic, gasses and particles from Kilauea volcano exerted an influence on Tropical Storm Flossie – affecting the formation of thunderstorms and lightning in the sizeable storm.
In July 2013, as Flossie approached the Hawaiian Islands, satellites steadily monitored lightning, rainfall, cloud cover, temperature and winds. In addition, UHM graduate assistant Andre Pattantyus and UHM Atmospheric Science Professor Dr. Steven Businger dutifully maintained their vog model – a forecasting tool Businger has operated since 2010 to provide guidance on the location of the vog plume and the concentrations of sulfur dioxide (SO2) and sulfate aerosol for Hawaiian Island communities.
In assessing the vog model, “We noticed the curious spiral pattern of vog being entrained into Hurricane Flossie and decided to dig deeper by looking at satellite and lightning data sets,” said Businger, co-author of the study.
He and lead author Pattantyus found that prior to Flossie’s passage over the island of Hawai‘i, the observation network detected no lightning in the storm. Though one hour later, vigorous lightning flashed in the vicinity of the Island of Hawaiʻi as Flossie approached. Further, as volcanic emissions were wrapped into this moist environment, sulfate aerosols promoted the formation of a greater number of smaller than normal cloud droplets, which favored charge separation in the upper cloud region and the occurrence of lightning.
Sulfate aerosols have previously been identified as a principal component of cloud condensation nuclei (CCN), a necessary ingredient for forming raindrops. But, said Businger, “This is the first interaction between an active, vigorously degassing volcano and a tropical cyclone captured by a vog model run over the Hawaiian Islands – providing a unique opportunity to analyze the influence of robust volcanic emissions entrained into a tropical storm system.”
Taken together, the observations and the vog model highlight an intimate interaction between Tropical Storm Flossie and Kilauea’s vog plume during the passage of the storm. The observations of Flossie’s changing dynamics as it encountered Kilauea’s vog has implications for the impact on hurricanes of polluted air as they approach the U.S. mainland coast.
“The Hawaiian Islands provide a unique environment to study this interaction in relative isolation from other influences,” according to Businger. He plans to model the interaction of the vog plume and Hurricane Flossie with a more complex model that integrates chemistry into the predictions to better understand the processes at work in this unique confluence.
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Pattantyus, A., and S. Businger (2014). On the interaction of Tropical Cyclone Flossie and emissions from Hawaiʻi’s Kilauea volcano, Geophysical Research Letters, 41, doi:10.1002/2014GL060033.
The School of Ocean and Earth Science and Technology at the University of Hawaiʻi at Mānoa was established by the Board of Regents of the University of Hawai‘i in 1988 in recognition of the need to realign and further strengthen the excellent education and research resources available within the University. SOEST brings together four academic departments, three research institutes, several federal cooperative programs, and support facilities of the highest quality in the nation to meet challenges in the ocean, earth and planetary sciences and technologies.