We acknowledge logistic support from Southern Cross University, Lismore, and its staff at the National Marine Science Centre and NORSEARCH. We thank Fabio Carocci for preparing Fig. 1 and Chris Barlow and Lindsay Chapman for early guidance on the workshop structure. “
“Modern humans have exploited marine resources since we emerged as a species (see, e.g., [1]). When harsh conditions threatened the small population of early humans, coastal marine resources allowed them
to survive [2]. But since then, human have thrived, and have strongly impacted marine, and particularly learn more coastal species and ecosystems [3], especially in the last 150 years, which saw the industrialization of fisheries [4]. Notably, global fishing patterns have strongly changed since the Food and Agriculture Organization of the United Nations published its first collection of global fisheries landings in the mid 1950s [5]. Fishing fleets selleckchem have been challenged by stock collapses [6], while empowered by improved technologies and logistic support. Many fisheries are now multinational enterprises (see, e.g., [7] and [8]). Since the adoption, in the late 1970s/early 1980s of exclusive economic
zones (EEZ) by maritime countries [9], the roving fleets of distant-water countries have had to negotiate coastal zone access arrangements. Though maps of where fishing occurs have always accompanied this activity, these documents were seen as commercially valuable, and were not willingly disclosed, as fishing is, of course, a very competitive business. Trying to see the big picture has therefore been extremely difficult, while increasingly necessary to examine potential impacts
on marine ecosystems, and those commercial and non-commercial plants and animals embedded in them. Additionally, the impacts of climate change will challenge our ability to plan and mitigate [10]. The Sea Around Us project, which began in 1999 ( [11] and [12]), has used publicly available fisheries landing statistics, to map where global landings were taken on a fine-scale [13] and [14]. Subsequently, this same project mapped global fishing effort as well [15], [16] and [17]. These Bumetanide mapped databases allow fishing activity to be associated on a spatial scale of use to policy makers and ecologists alike, especially when the data they presented were refined to allow a breakdown by fishing country and associated fishing gear. Such data breakdowns allowed for comparison with oceanographic and satellite data such as primary productivity [18], [19] and [20], as one of the most potent measures of fishing intensity is how much of local primary production is appropriated in form of fisheries catches.