fungal spores, microorganisms, and

fungal spores, microorganisms, and pollen. The isoprene-related SOA markers comprised 2-methyltetrols [2-methylthreitol (2MT) and 2-methylerythritol (2ME)], 2-methylglyceric acid (2MG), and C5-alkene triols (Claeys et al., 2004a, 2004b; Wang et al., 2005;Surratt et al., 2006), whereas the monosaccharides, fructose and glucose, are related with microorganism and plant emissions (Caseiro et al., 2007), and the polyols, arabitol and mannitol, are markers for fungal spores (Bauer et al., 2008). Of these, the monosaccharides could also be emitted into the atmosphere upon
sugarcane burning (Scaramboni et al., 2015). Furthermore, in order to evaluate whether anhydrosugar ratios (i.e., levoglucosan/mannosan and levoglucosan/galactosan ratios) can provide some information on the type of biofuel, aerosol samples were also collected in Piracicaba, in the vicinity of S~ ao Paulo, during the 2014 sugarcane cultivation period, and analyzed for monosaccharide anhydrides, considering that hemicelluloses from sugarcane residue have a relatively high galactose (monosaccharide precursor of galactosan) content (Peng et al., 2009). It is known that the levoglucosan/mannosan ratio can give some indication about the type of biofuel used in BB. Distinctly different ratios have been reported for softwood (range 3.6e6.7) and hardwood (range 13e24) burning (Fine et al., 2004; Schmidl et al., 2008), while rice straw burning results in typical high ratios (range 40e42), due to the relatively low mannose (monosaccharide precursor of mannosan) content in the hemicelluloses (Sheesley et al., 2003; Engling et al., 2009). The anhydrosugar ratios obtained for the samples collected in SPA were compared with those for Piracicaba in the area of sugarcane cultivation and other Brazilian sites in Rondonia which are impacted by forest fires whe