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Earth-System and regional models, forecasting climate change and its impacts, simulate atmosphere\u2013ocean gas exchanges using classical yet too simple generalizations relying on wind speed as the sole mediator while neglecting factors as sea-surface agitation, atmospheric stability, current drag with the bottom, rain and surfactants. These were proved fundamental for accurate estimates, particularly in the coastal ocean, where a significant part of the atmosphere\u2013ocean greenhouse gas exchanges occurs. We include several of these factors in a customizable algorithm proposed for the basis of novel couplers of the atmospheric and oceanographic model components. We tested performances with measured and simulated data from the European coastal ocean, having found our algorithm to forecast greenhouse gas exchanges largely different from the forecasted by the generalization currently in use. Our algorithm allows calculus vectorization and parallel processing, improving computational speed roughly 12\u00d7 in a single cpu core, an essential feature for Earth-System models applications.<\/jats:p>","DOI":"10.5194\/bgd-12-15901-2015","type":"posted-content","created":{"date-parts":[[2015,9,28]],"date-time":"2015-09-28T05:00:47Z","timestamp":1443416447000},"source":"Crossref","is-referenced-by-count":0,"title":["Improving estimations of greenhouse gas transfer velocities by atmosphere\u2013ocean couplers in Earth-System and regional models"],"prefix":"10.5194","author":[{"given":"V. M. N. C. 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