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    The datafile contains the composition and abundance of airborne pollen in the suburb of Casuarina, Darwin, Northern Territory, Australia. The data was collected for the period between March 2004 to November 2005 as part of a large research program looking at atmospheric particles and human health (see Stevenson et al., 2007).

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    The datafile contains the composition and abundance of airborne pollen in the suburb of Sandy Bay (University of Tasmania), Hobart, Tasmania, Australia. The data was collected for the period between July 2007 to December 2010 as part of a large research program looking at atmospheric particles and human health and phenology of urban planted environments (see Tng et al., 2010).

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    The datafile contains the composition and abundance of airborne pollen in the suburb of Rocklea, Brisbane, Queensland, Australia. The data was collected for the period between June 1994 to May 1999 as part of a research program that assessed pollen bioaerosols and relationships with meteorological parameters (Green et al., 2002). This forms part of a study of the Australian Aerobiology working group (Haberle, Bowman, Newnham, Johnston, Beggs, Buters, Campbell, Erbas, Godwin, Green, Heute, Jaggard, Medek, Murray, Newbiggin, Thibaudon, Vicendese, Williamson, Davies “The macroecology of airborne pollen in Australian and New Zealand urban areas”).

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    The datafile contains the composition and abundance of airborne pollen in the suburb of Campbelltown (University of Western Sydney), Sydney, NSW, Australia. The data was collected for the period between August 1992 to December 1995 as a study presented by Bass and Morgan (1997). This forms part of a study of the Australian Aerobiology working group (Haberle, Bowman, Newnham, Johnston, Beggs, Buters, Campbell, Erbas, Godwin, Green, Heute, Jaggard, Medek, Murray, Newbiggin, Thibaudon, Vicendese, Williamson, Davies “The macroecology of airborne pollen in Australian and New Zealand urban areas”).

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    The datafile contains the composition and abundance of airborne pollen in Onehunga, Auckland, New Zealand. The data was collected for the period between October 1989 to April 1990 as part of a nationwide survey of airborne pollen. This forms part of a study of the Australian Aerobiology working group (Haberle, Bowman, Newnham, Johnston, Beggs, Buters, Campbell, Erbas, Godwin, Green, Heute, Jaggard, Medek, Murray, Newbiggin, Thibaudon, Vicendese, Williamson, Davies “The macroecology of airborne pollen in Australian and New Zealand urban areas”).

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    The datafile contains the composition and abundance of airborne pollen collected at the University of Melbourne campus at Parkville, Melbourne, Australia for the MAPCAH study. The data were collected between September 2009 and December 2011 as part of a research program looking at the relationship between airborne pollen and asthma exacerbations in children and adolescents (Erbas et al., 2012). These data have been included as part of a study of the Australian Aerobiology working group (Haberle, Bowman, Newnham, Johnston, Beggs, Buters, Campbell, Erbas, Godwin, Green, Heute, Jaggard, Medek, Murray, Newbigin, Thibaudon, Vicendese, Williamson, Davies “The macroecology of airborne pollen in Australian and New Zealand urban areas”).

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    The TREND (PSRF)- Terrestrial Ecosystems project initiated a landscape-scale monitoring transect along the Adelaide Geosyncline region in southern Australia, initially spanning approximately 550 km. The aim was to examine spatial drivers of species composition and to isolate the influence of climate on whole vegetation community composition and therefore inform on-going monitoring of the impact of climate change. Specific questions were: 1. What are the most important spatial drivers of species and phylogenetic composition along landscape-scale environmental gradients? 2. Can the answer to Question 1. inform selection of suitable spatial analogues for climate change? 3. How can a framework for assessing spatial drivers be used to monitor and interpret shifts in species composition due to climate change? The dataset consists of site and species records (see attachments) for plots established along the Adelaide Geosyncline for the TREND project. Data consist of vascular plant species composition (presence-abundance/absence) within 900m<sup>2</sup> plots plus site data, including aspect and soil properties. Data have been used to analyze changes in composition with geographic and environmental differences and as a baseline for monitoring.