Author:
Zaman M.,Kleineidam K.,Bakken L.,Berendt J.,Bracken C.,Butterbach-Bahl K.,Cai Z.,Chang S. X.,Clough T.,Dawar K.,Ding W. X.,Dörsch P.,dos Reis Martins M.,Eckhardt C.,Fiedler S.,Frosch T.,Goopy J.,Görres C.-M.,Gupta A.,Henjes S.,Hofmann M. E. G.,Horn M. A.,Jahangir M. M. R.,Jansen-Willems A.,Lenhart K.,Heng L.,Lewicka-Szczebak D.,Lucic G.,Merbold L.,Mohn J.,Molstad L.,Moser G.,Murphy P.,Sanz-Cobena A.,Šimek M.,Urquiaga S.,Well R.,Wrage-Mönnig N.,Zaman S.,Zhang J.,Müller C.
Abstract
AbstractMicrometeorological techniques are useful if greenhouse gas (GHG) emissions from larger areas (i.e. entire fields) should be integrated. The theory and the various techniques such as flux-gradient, aerodynamic, and Bowen ratio as well as Eddy correlation methods are described and discussed. Alternative methods also used are Eddy correlation, mass balance techniques, and tracer-based methods. The analytical techniques with current state-of-the-art approaches as well as the calculation procedures are presented.
Publisher
Springer International Publishing