The Smooth Hammerhead (Sphyrna zygaena) is a large (to 400 cm total length) coastal and semi-oceanic pelagic shark, wide-ranging in temperate and tropical seas to depths of at least 200 m, possibly 500 m. Population growth rates of 0.225 per year are among the fastest known for pelagic sharks and the fastest of the hammerhead species. The Smooth Hammerhead is caught globally as target and bycatch in coastal and pelagic commercial and small-scale longline, purse seine, and gillnet fisheries, and is often retained for the fins, and sometimes the meat. It has undergone steep historic declines in the Atlantic but the introduction of management measures may be allowing slow recovery, lesser declines in the South Pacific, and increases in the Indian Ocean. The weighted global population trends estimated a median reduction of 21.8–64.8%, with the highest probability of <20% and >80% reduction over three generation lengths (72.3 years). The Northwest Atlantic data that includes the period after management changes led to the lower estimated global reduction. However, there is uncertainty in some of the catch data, limited regional representation of some time-series, and intensive-fisheries in data-poor regions that are suspected to have driven declines, balanced with the relatively lower level of artisanal fisheries threat to this species compared to that of the Scalloped Hammerhead (S. lewini) and Great Hammerhead (S. mokarran), due to its generally more temperate distribution. Expert judgement elicitation thus inferred a global population reduction of 30–49% and the Smooth Hammerhead is therefore assessed as Vulnerable A2bd. More robust species-specific data and monitoring of catches is required to improve certainty of catch estimates for a future assessment of this species.

The Smooth Hammerhead occurs worldwide in temperate seas and in some regions, it is present in tropical seas (Last and Stevens 2009, Ebert et al. 2013, Bezerra et al. 2018).

There are no data available on the global population size of the Smooth Hammerhead. Genetic studies reveal structure between the Atlantic and Indo-Pacific, however contrasting results may indicate female philopatry and male mediated gene flow (Testerman 2014).

Population trend data are available from four sources: (1) stock assessment in the Northwest Atlantic and Gulf of Mexico (Jiao et al. 2011), and from standardized catch-per-unit-effort (CPUE) in: (2) the Northwest Atlantic and Gulf of Mexico (J. Carlson unpubl. data); (3) the South Pacific (Reid et al. 2011) and, (4) the Indian Ocean (Dicken et al. 2018). The trend data from each source were analyzed over three generation lengths using a Bayesian state-space framework (a modification of Winker et al. 2018). This analysis yields an annual rate of change, a median change over three generation lengths, and the probability of the most likely IUCN Red List category percent change over three generations (see the Supplementary Information).

First, the Northwest Atlantic stock assessment for 1981–2005 indicated that the stock was overfished from the mid-1980s with overfishing occurring continuously from 1994–1998, and the risk of overfishing generally low after 2001 when catches dramatically reduced (Jiao et al. 2011). A previous stock assessment found significant historical declines and that abundance had stabilized since the late 1990s (Hayes 2008); however, both stock assessments report a high degree of uncertainty mostly due to poor catch data that includes very low sample sizes, unreliable data due to the scarcity of Smooth Hammerhead in fisheries catches, and issues with accurate species identification (Miller 2016). The trend analysis of the Northwest Atlantic modeled abundance for 1981–2005 (25 years) revealed an annual rate of reduction of 7.0%, consistent with an estimated median reduction of 99.6% over three generation lengths (72.3 years), with the highest probability of >80% reduction over three generation lengths. 

Second, more recent data (1992–2017) are available from Northwest Atlantic and Gulf of Mexico comprising the pelagic longline observer time-series underlying the Jiao et al. (2011) stock assessment for Smooth Hammerhead (J. Carlson unpubl. data). The time-series indicate this population has slowly begun to increase after the implementation of management after 2005 (NMFS 2006). The trend analysis of the CPUE for 1992–2017 (26 years) revealed an annual rate of increase of 0.8% with a median increase and the highest probability of an increase over three generation lengths (72.3 years). 

Third, hammerhead catches in the New South Wales (Australia) beach meshing program, which comprised predominantly Smooth Hammerhead, fluctuated over 60 years with strong declines from 1990–2010 (Reid et al. 2011). The trend analysis of the CPUE for 1950–2009 (60 years) revealed an annual rate of reduction of 3.0%, consistent with an estimated median reduction of 17.9% over three generation lengths (72.3 years), with the highest probability of <20% reduction over three generation lengths. 

Fourth, the Smooth Hammerhead CPUE in the South Indian Ocean Natal Shark’s Board bather protection netting program varied markedly over 1978–2014 with a slight, but not significant, increasing trend (Dicken et al. 2018). The analysis of the CPUE for 1978–2014 (37 years) revealed an annual rate of increase of 0.6% with a median increase and the highest probability of an increase over three generation lengths (72.3 years). 

Further to the above data and trend analysis, standardized CPUE data from the Portuguese longline fishery in the Eastern Central and Southwest Atlantic for 2008–2016 indicated fluctuations for 2008–2010, a decrease till 2013 then an increase back to 2008 catch levels in 2016 (Santos and Coelho 2019). We considered a recent analysis of fishery-dependent longline CPUE from the South Atlantic. These time-series are complex, reflecting access by different fleets and nationalities over time, but the best estimates of trends come from phase B spanning 1998 to 2008 during which twenty fleets (100 vessels) fished for tunas, swordfishes, and sharks. During this 10-year period there was a 61.7% decline in CPUE of hammerheads (Sphyrna spp.) (Table S11, Barreto et al. 2016), however, because the data were not considered robust due to the low catch rates and large confidence intervals (R. Barreto unpubl. data), they were not analyzed over three generations. 

In the Southeast Pacific, landings of Smooth Hammerheads in Peruvian small-scale gillnet fisheries (1996–2010) peaked in 1998 and 2003 at ~1,500 tonne annually, but for the remainder of the period were fairly stable at 200–300 tonne annually (Gonzalez-Pestana et al. 2016). Without any effort data, it is not possible to ascertain if this is a reflection of stock abundance trends (Miller 2016). Population trend data from the North Pacific and Western Central Pacific is limited. In the North Pacific, landings of Smooth Hammerhead from Taiwan comprise a small proportion (1.38%; ~78 tonne) of the annual catch and although catches have declined in recent years, so too has the fishing effort and it is not possible to determine a population trend (Miller 2016). In the Western Central Pacific, hammerhead catches are for the species-complex, with no indication of the proportion of Smooth Hammerheads. The CPUE (1995–2015) was highly variable and as Smooth Hammerhead are captured infrequently, little inference was possible from the temporal trend (Rice et al. 2015). An analysis of Smooth Hammerhead yield- and biomass-per-recruit on the Kerala coast, India in the Northern Indian Ocean for 2008–2009, indicated that the stock was over-exploited (Manjusha et al. 2011). Fishing pressure has significantly increased in recent decades across the distribution of the Smooth Hammerhead in the tropical Western Indian Ocean (Cooke 1997, Jabado et al. 2017), and has likely caused declines in this region.

Steep declines of hammerheads (Sphyrna spp.) have occurred in the Mediterranean Sea; Ferretti et al. (2008) compiled nine time-series of abundance indices from commercial and recreational fishery landings, scientific surveys and sighting records, to reconstruct long-term population trends of large sharks in the northwest Mediterranean Sea. Of the taxa for which there were enough data to investigate, hammerhead sharks declined the fastest; disappearing from coastal waters after 1963 followed by declines (across all fishing sectors) in pelagic waters by the early 1980s. Meta-analysis showed an average instantaneous rate of decline in abundance of -0.17 (time range 178 years) and biomass of -0.36 (time range 107 years), which equates to an estimated decline of 99.99% in abundance and biomass since the early 19th century (Ferretti et al. 2008). Walker et al. (2005) also report that hammerhead species have virtually disappeared from the central-southern Mediterranean Sea since 1986. 

The Smooth Hammerhead trend analyses estimated historic declines in the Atlantic and South Pacific, and an increase in the Southern Indian Ocean. There are some signs of stabilization and possible recovery in response to management in the Northwest Atlantic and Gulf of Mexico, fluctuating but overall stable catches in the Eastern Central and Southwest Atlantic in 2016, over-exploited stocks in the Northern Indian Ocean, and likely declines in the tropical Western Indian Ocean due to intense fishing pressure. To estimate a global population trend, the estimated three generation population trends for each region (Atlantic, South Pacific, and Indian) were weighted according to the relative size of each region; the two sources of North Atlantic were used to generate two global trends. This resulted in a median reduction of 21.8–64.8%, with the highest probabilities of <20% and >80% reduction over three generation lengths (72.3 years). The second Northwest Atlantic data that includes the period after management changes led to a far lesser estimated global reduction, yet it needs to be considered that all time-series are from limited areas within each region and may not accurately represent the trend in Smooth Hammerhead across the entire region. There is uncertainty in some of the catch data and levels of exploitation; the regions with no trend data are likely areas where the species is under the most pressure, such as the tropical Western Indian Ocean. Yet, the Smooth Hammerhead is a generally more temperate species than the Scalloped Hammerhead and Great Hammerhead and thus, the majority of its distribution is not as exposed to the same level of threat from intense artisanal fisheries. Based on the considerations of possible recovery in areas with managed fisheries, potential declines in intensively fished data-poor regions, and less relative exposure to artisanal fisheries than the other two large hammerhead species, expert judgement elicitation inferred a global population reduction of 30–49% over three generation lengths (72.3 years). More robust species-specific data and monitoring of catches is required to improve certainty of catch estimates for a future assessment of this species.

The Smooth Hammerhead is a coastal and semi-oceanic pelagic shark that occurs on the continental shelf to at least 200 m depth, and possibly 500 m (Ebert et al. 2013, Weigmann 2016). It is the most oceanic of the hammerhead species, commonly leaving coastal habitats at 2–3 years of age (Clarke et al. 2015). Despite its widespread occurrence, biological data on this species is limited. It attains a maximum size of 370–400 cm total length (TL) (Ebert et al. 2013, Weigmann 2016). Males mature at 250–260 cm TL and females at about 246–265 cm TL (Stevens 1984, Castro and Mejuto 1995). Reproduction is viviparous with litter sizes of 20–50, a gestation period of 10–11 months, unknown reproductive periodicity, and a size-at-birth of 49–63 cm TL (Stevens 1975, Stevens 1984, Smale 1991, Castro and Mejuto 1995, Doño 2008, Francis 2010, Ebert et al. 2013, Clarke et al. 2015, Rosa et al. 2017, Gallagher and Klimley 2018). Female age-at-maturity is estimated as 15 years based on size-at-maturity and the growth curves from Rosa et al. (2017). The maximum ages observed are 24 years for females and 25 years for males (Rosa et al. 2017). However, these are unlikely to be the true maximum ages as individuals from the study were a maximum size of 286 cm TL, considerably less than the known maximum size (Rosa et al. 2017). Generation length is estimated at 24.1 years based on that of Scalloped Hammerhead which reaches a similar size and has a maximum age of 35 years (Drew et al. 2015). Population growth rate estimate is among the fastest of the known pelagic sharks and the fastest of the hammerhead species at 0.225 per year (Cortés et al. 2012).

The Smooth Hammerhead is caught globally as target and bycatch in commercial and small-scale pelagic longline, purse seine, and gillnet fisheries. It is also captured in coastal longlines, gillnets, trammel nets, and sometimes trawls, particularly in areas with narrow continental shelves, and in some areas, such as Peru, this includes capture of pregnant females and juveniles (White et al. 2006, Camhi et al. 2008, Gonzalez-Pestana et al. 2016, Martínez-Ortiz et al. 2015). The species is often retained for the fins (Clarke et al. 2006a, Clarke et al. 2006b, Dent and Clarke 2015, Fields et al. 2018), unless regulations prohibit retention. Under-reporting of catches in pelagic and domestic fisheries is likely (Dent and Clarke 2015). High at-vessel mortality of 71% was estimated on Portuguese longlines in the Atlantic (Coelho et al. 2012). The post-release mortality is higher for injured released sharks; it has been reported as 100% for the closely-related Scalloped Hammerhead in purse seines (Eddy et al. 2016). The Smooth Hammerhead is taken in beach protection programs that target large sharks with high mortality in the beach mesh nets in New South Wales of ~95% prior to 2010; nearly all of the Smooth Hammerhead catch is juveniles (Dudley and Simpfendorfer 2006, Simpfendorfer et al. 2010, Reid et al. 2011). 

The main product from the species that is traded is the fins (CITES 2013). Hammerhead fins are among the main shark species in the fin trade and one of the preferred species for shark fin soup (Clarke et al. 2006a, Dent and Clarke 2015, Fields et al. 2018). Smooth Hammerhead accounted for 1.7% of the fin imported and was the fourth most abundant traded fin species in Hong Kong in 2014 (Fields et al. 2018). The meat, liver oil, skin, cartilage, and jaws may also be used (White et al. 2006, Miller 2016, Almerón-Souza et al. 2018).

The success of actions agreed through international wildlife and fisheries treaties depends on implementation at the domestic level; for sharks, such follow up actions have to date been seriously lacking.

In 2010, the International Commission for the Conservation of Atlantic Tunas (ICCAT) prohibited retention, transshipment, landing, and sale of Great Hammerheads (and other hammerhead species) for ICCAT fisheries operating in the Convention Area. There are exceptions for local consumption in developing countries, provided they cap catches, meet catch data reporting requirements, and ensure fins are not traded internationally. The Western and Central Pacific Fisheries Commission (WCPFC) designated the Great Hammerhead as a 'key shark species' in 2010, but has yet to adopt hammerhead catch limits. Several proposals to ban hammerhead landings and/or set regional hammerhead fishing limits through the Inter-American Tropical Tuna Commission (IATTC) have been defeated.

In 2013, the Smooth Hammerhead was added to Appendix II of the Convention on International Trade in Endangered Species (CITES) based on its similarity to the Scalloped Hammerhead. The listing requires CITES Parties to ensure that exports be accompanied by permits based on findings that parts are sourced from legal and sustainable fisheries. In 2018, the Smooth Hammerhead was added to Annex 1 of the Convention on Migratory Species (CMS) Memorandum of Understanding (MoU) for Migratory Sharks, even though the species has not (yet) been included on the CMS Appendices. The MoU is aimed at facilitating regional conservation of listed shark and ray species. Great and Scalloped Hammerhead Sharks were listed on CMS Appendix II in 2014. Initiatives to prevent capture, minimize bycatch mortality, promote safe release, and improve catch (including discard) reporting are needed, as is full implementation of additional commitments agreed through international treaties.