Abstract
The accumulation of aquatic organisms on the wetted surfaces of vessels (i.e., vessel biofouling) negatively impacts world-wide shipping through reductions in vessel performance and fuel efficiency, and increases in emissions. Vessel biofouling is also a potent mechanism for the introduction and spread of marine non-indigenous species. Guidance and regulations from the International Maritime Organization, New Zealand, and California have recently been adopted to address biosecurity risks, primarily through preventive management. However, appropriate reactive management measures may be necessary for some vessels. Vessel in-water cleaning or treatment (VICT) has been identified as an important tool to improve operating efficiency and to reduce biosecurity risks. VICT can be applied proactively (i.e., to prevent the occurrence of, or to remove, microfouling (i.e., slime) or prevent the occurrence of macrofouling organisms - large, distinct multicellular organisms visible to the human eye), or reactively (i.e., to remove macrofouling organisms). However, unmanaged VICT includes its own set of biosecurity and water quality risks. Regulatory policies and technical advice from California and New Zealand have been developed to manage these risks, but there are still knowledge gaps related to the efficacy of available technologies. Research efforts are underway to address these gaps in order to inform the regulatory and non-regulatory application of VICT.
Highlights
Biofouling is the accumulation of aquatic organisms on immersed surfaces
To minimize the risk of marine non-indigenous species (NIS) transfers associated with the vessel biofouling pathway, guidelines (International Maritime Organization [IMO], 2011, 2012) and regulations (Ministry for Primary Industries, New Zealand [MPI], 2014; California Code of Regulations, 2017) have been developed at international, national, and regional levels
The economic benefit of removing the slime layer by Proactive In-Water Cleaning (PIC) has been the subject of many studies (e.g., Schultz et al, 2011) and, while the magnitude of economic benefit requires further clarity, PIC aligns with efforts by the International Maritime Organization (IMO) to reduce greenhouse gas emissions by optimizing vessel fuel efficiency (International Maritime Organization [IMO], 2011)
Summary
Biofouling is the accumulation of aquatic organisms on immersed surfaces. Biofouling on maritime vessels is an ongoing burden for owners and operators (reviewed by Woods Hole Oceanographic Institute [WHOI], 1952), causing impacts on speed, maneuverability, operability, and durability. To minimize the risk of marine NIS transfers associated with the vessel biofouling pathway, guidelines (International Maritime Organization [IMO], 2011, 2012) and regulations (Ministry for Primary Industries, New Zealand [MPI], 2014; California Code of Regulations, 2017) have been developed at international, national, and regional levels. All guidelines and regulations identify vessel in-water cleaning or treatment (VICT; Table 1) as an important tool to maintain a vessel as free of biofouling as practical minimizing biosecurity risk (International Maritime Organization [IMO], 2011; Department of the Environment [DOE] and New Zealand Ministry for Primary Industries [MPI], 2015; Scianni et al, 2017; Georgiades et al, 2018). There are two approaches to VICT: Proactive in-water cleaning (PIC) or treatment (PIT), which for the purposes of this review includes hull grooming (e.g., Tribou and Swain, 2015), is used to prevent or reduce the attachment and growth of microfouling (i.e., slime) on the vessel and to remove newly attached (i.e., microscopic)
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