3.2.1 Projectile Hunting: Changes for the Better

Like most aspects of early biological and cultural evolution (e.g. Groucutt et al. Reference Groucutt, Petraglia and Bailey2015), the origin and development of projectile technology remain poorly understood. The earliest evidence for launched weapons used in both hunting and warfare for any hominid comes from several wooden spears found in Schöningen, Germany. These spears, dated ~400,000 BP, that is before the emergence of modern humans (Thieme Reference Thieme1997), were either hand-held, short-ranged thrusting weapons (Shea Reference Shea2006; Thieme Reference Thieme1997) or throwing weapons for distances up to 20 metres (Milks et al. Reference Milks, Parker and Pope2019). Relatively large, heavy spears sometimes tipped with stone armatures were typical of Neanderthal hunting, where Neanderthal upper limb and upper body morphology has been suggested to be an adaptation to the energetic and mechanical requirements of using thrusting spears (Churchill Reference Churchill and Churchill2014). Thrusting and short-distance throwing spears preconditioned hunting strategies, and hunting with spears has often been equated with large hunter group size (Wadley Reference Wadley2010). The subsequent appearance of distance weapons is a critical development in human hunting technology. As a result, the arsenal of spears used by AMH was considerably larger, compared to Neanderthals who only used thrusting spears (Churchill Reference Churchill and Churchill2014) or short-distance throwing lances (Milks et al. Reference Milks, Parker and Pope2019). What were previously thought to be the oldest-known spears, those found in Clacton-on-Sea, UK (Oakley et al. Reference Oakley, Andrews, Keeley and Clark1977), and Lehringen, Germany (Movius Reference Movius1950), dated to the Middle Pleistocene, have been debated because associated faunal remains do not necessarily demonstrate hunting (Klein Reference Klein, Nitecki and Nitecki1987). For example, the Lehringen spear was found between the ribs of an elephant skeleton, but some authors have suggested that these sites are spring-, stream- or lakeside localities where it is difficult to separate bones that may represent natural deaths from human kills (Klein Reference Klein, Nitecki and Nitecki1987). By contrast, the association of the Schöningen spears with stone tools and butchered remains of more than ten horses confirms them as hunting weapons, suggesting that systematic hunting that employed projectile technology was already present in pre-modern hominids.

The oldest backed stone blades have been found at Twin Rivers, Zambia, in deposits of approximately 300,000 BP (Barham Reference Barham2002). Backed stone blades have one thick, blunt side suitable for hafting, with the attachment of the blades to wooden spears or arrows (Fig. 3.3). The design and preparation of backed tools, the preparation of hafts and the final hafting require problem-solving and planning that is usually associated with modern humans (Ambrose Reference Ambrose2001). Indeed, new fossil finds, identified as Homo sapiens, from Jebel Irhoud, Morocco, place backed tool preparation at the same time as the emergence of AMH in Africa. These fossils, dated 315,000 ± 34,000 BP, show a mosaic of key modern human morphological features of early or recent AMH and more primitive cranial morphology (Hublin et al. Reference Hublin, Ben-Ncer and Bailey2017). The new technology together with new behaviour, including syntactic language, possibly allowed modern humans to expand their range into previously unoccupied Congo Basin tropical forests (Barham Reference Barham, Barham and Robson-Brown2001). Backed stone blades have been confirmed in East Africa at ~130,000 BP (Mehlman Reference Mehlman1990) and in southern Africa between ~70,000 and ~60,000 BP (Wadley & Mohapi Reference Wadley and Mohapi2008). The latter paper describes Howiesons Poort Industry tools from Sibudu in South Africa, which are particularly interesting as they comprise diverse stone projectiles linked to different types of hunting tools. Tools made from dolerite were relatively large, too large for arrow heads, but suitable for darts and spearheads. Quartz tools were of a size of arrowheads, whilst hornfels tools varied in size and appear to have been reused during their lifetime for different purposes by reshaping. Trace analyses suggest that most tools were parts of hunting weapons, in particular bows and arrows (Lombard & Phillipson Reference Lombard and Phillipson2010; Wadley & Mohapi Reference Wadley and Mohapi2008).

Figure 3.3 Backed tools from Twin Rivers.

(from Barham Reference Barham2002 reprinted with permission from Elsevier)

Although lithic projectile weaponry has been confirmed across Africa before ~50,000 BP, it appears not to have been widespread or in regular use in this continent, in Europe or the Levant (Shea Reference Shea2006). However, by 45,000–40,000 BP, lithic projectiles were in use in most parts of the world occupied by humans (Knecht Reference Cattelain and Knecht1997), after dispersing out of Africa and arriving at the periphery of the Old World, Australia, Siberia and northwest Europe by 50,000–40,000 BP (Groucutt et al. Reference Groucutt, Petraglia and Bailey2015). This widespread use of distance weapons for large animal hunting and warfare is regarded as an epiphenomenon of the ‘Upper Palaeolithic’ behavioural revolution as it involves planning, social organization and the application of suitable technology. Such use of projectile weapons allowed the more accurate killing of large, potentially dangerous prey at a safe distance compared to hand-delivered thrusting methods. The contention is that these technological changes diminished the need for muscular strength, thus affording the more gracile anatomically modern humans a competitive advantage over Neanderthals (Churchill & Rhodes Reference Churchill and Rhodes2006). Moreover, the development of mechanically delivered projectile weapons, spearthrower-darts or bows and arrows, further improved hunting efficiency in modern humans. The earliest evidence of mechanically delivered projectile weapons was found at Grotta del Cavallo in southern Italy, discovered alongside signs of hunting of young horses (Sano et al. Reference Sano, Arrighi and Stani2019). These projectiles, dated to between 40,000 and 45,000 BP, correspond to the early migration period of modern humans into Eurasia (Groucutt et al. Reference Groucutt, Petraglia and Bailey2015; O’Connell et al. Reference O’Connell, Allen and Williams2018). The Grotta del Cavallo projectiles pre-date the previously known spearthrowers and arrows from France and Germany by more than 20,000 years (Cattelain Reference Cattelain and Knecht1997; Sano et al. Reference Sano, Arrighi and Stani2019).

3.2.2 Nets, Traps, Snares and Other Methods

In contrast to lithic artefacts and, in some cases, larger wooden fragments, materials such as fibres do not preserve well in the archaeological record. Evidence for hunting with nets, traps and snares is therefore rare; such information is, however, of importance for our understanding of human evolution. The operation of these techniques constitutes a significant milestone in the development of memory and cognition in planning across space and time (Wynn & Coolidge Reference Wynn and Coolidge2003). Nonetheless, indirect evidence from the Sibudu site in South Africa points to the use of snares during the Howiesons Poort Industry ~65,000–60,000 BP, possibly even ~70,000 BP (Wadley Reference Wadley2010). The high frequency and the relatively high taxonomic diversity of comparatively small mammals found at the site are consistent with modern snare hunting (Chapter 6) and not with hunting with projectile weaponry (bows and arrows or spears). This follows from our understanding of optimal foraging strategies (Chapter 4), which indicates that hunters prefer larger prey, especially when faunal assemblages are not depleted by overhunting, since during the Pleistocene human population density was likely to have been low. In Sibudu, the high frequency of small carnivores (including felids, viverrids, mongooses, mustelids and canids) does not suggest net hunting as these species are difficult to capture with this method but are easily caught with snares or traps. Trapping of carnivores often requires bait, often living. Using one prey animal to catch another presupposes a certain commitment to catch the carnivore. Generally, catching carnivores is more about protection against physical harm by such animals than for food since their meat is rarely preferred (see Section 3.4). The high number of carnivore remains in Sibudu suggest that they may have been caught for symbolic, medicinal or magic reasons, e.g. for their fur, teeth and claws. The high frequency of bushpig remains in Sibudu also suggests snare hunting because the species is nocturnal and dangerous to hunt. Although net hunting for bushpigs could have occurred, as demonstrated by Pygmy net hunters (Dounias Reference Dounias2016), these animals are strong enough to tear nets or break through the line of beaters rather than be cornered (Skinner & Chimimba Reference Skinner and Chimimba2005). The abundant remains of blue duiker, a common forest antelope, may point also to snaring since this relatively small animal is widely caught nowadays with snares throughout West and Central Africa (Fa et al. Reference Fa, Ryan and Bell2005) but is more difficult to hunt with bow and arrow or spears. However, duikers can be attracted in to the open by hunters imitating the call of a distressed animal (Brosset Reference Brosset1966; van Vliet et al. Reference Van Vliet, Kaniowska, Bourgarel, Fargeot and Nasi2009). Finally, there is evidence that faunal assemblages in Sibudu became less diverse during the more recent Pleistocene, with fewer small mammals, bushpig or blue duiker remains being found. Wadley (Reference Wadley2010) explains this change to be the result of larger hunter group sizes appearing as a result of population growth, thus allowing the hunting of large prey with spears. It is possible that, as observed in modern hunter-gatherers, as human group sizes increased large animals may have been primarily targeted by men, with the added benefit for the more skilled hunters to attain social prestige and kudos (see Section 3.4). Although in some contexts women are known to participate in active hunts with men (e.g. Aka Pygmy net hunting, Noss & Hewlett Reference Noss and Hewlett2001), until recently when snaring has become commonplace due to the use of more affordable and accessible cable (Noss Reference Noss1998b), trapping animals may have been largely pursued by women. This division of labour between the sexes has been postulated in Fa et al. (Reference Fa, Stewart, Lloveras and Vargas2013) to explain the difference in hunting techniques used by Neanderthals and AMH in Pleistocene Iberia. Snare hunting therefore introduces an alternative to large prey hunting which increases food security when men are unable to bring prey home. For the Hadza in East Africa, the chances of obtaining large prey was only 3% or 45 days of failure between successes, whereas snaring was successful with only one to three days of failure in-between and an overall success rate 40 times higher than that for large prey (Hawkes et al. Reference Hawkes, O‘Connell and Blurton Jones1991, Reference Alvard and Kuznar2001).

It is possible that pit trap hunting may have occurred as early as 40,000 BP. In a study in the Japanese Archipelago as many as 376 traps were excavated from 51 Pleistocene sites (Sato Reference Sato2012). These were pits of about 1–2 metres in diameter, which may have been used for medium-sized prey such as wild boar and deer. Similarly, pit traps of over 20 metres in diameter have been discovered in Mexico containing a large assemblage of mammoth bones (Instituto Nacional de Antropología e Historia (Mexico) 2019). With an age of ~15,000 years they stem from the period of the peopling of the Americas and attest the versatility of humans hunting animals for food.

The oldest known confirmed evidence of the use of poison for hunting purposes dates to about 24,000 BP from the Border Cave in South Africa (d’Errico et al. Reference d’Errico, Backwell and Villa2012a). Although the identification and interpretation of archaeological micro-residuals of arrow poison is notoriously difficult (Bradfield et al. Reference Bradfield, Wadley and Lombard2015), biochemical traces have been identified as arrow poison (d’Errico et al. Reference d’Errico, Backwell and Villa2012b). The technical and symbolic items also found at the site suggest that the Border Cave inhabitants used the same material culture 44,000 BP as today’s San people, predating by 24,000 years the current consensus for the emergence of San hunter-gatherer cultural adaptations. The findings include bone points that are identical to San poisoned arrow points. Arrow points dated 37,000–35,000 BP, which could have been used with poison, have also been found at the White Paintings Rock Shelter in Botswana (Robbins et al. Reference Robbins, Campbell, Brook, Murphy and Hitchcock2012). Today, San use beetle larvae and plant extracts to prepare poison for their arrow heads (Lee et al. Reference Lee, Lee and DeVore1976).

Another technological revolution appeared with the use of nets for hunting small and medium-sized prey. The first evidence for net hunting comes from the Pavlov and Dolní Věstonice sites in the Czech Republic (Pringle Reference Pringle1997; Soffer Reference Soffer, Roebroeks, Mussi and Svoboda2000, Reference Alvard, Gillespie and Alvard2004) where clay fragments have been found bearing impressions of nets woven from wild plants and dated ~27,000 to ~25,00 BP. Evidence of the use of these nets is the large number of hare, fox and other small mammal bones found in the same site. The suggestion is that net-hunting is likely to have played an important role for food acquisition, introducing communal hunting practices that allowed children and women to participate (Soffer Reference Soffer, Roebroeks, Mussi and Svoboda2000). In the case of Aka Pygmy forest foragers of the Central African Republic women net-hunt more frequently than men (Noss & Hewlett Reference Noss and Hewlett2001). In this particular context, women participated in net hunts when game was relatively abundant, they received relatively high caloric returns from hunting, they had access to the means/technology just as men, and importantly, Aka men did not prohibit them from participating. Thus, systems that are flexible between the sexes and ages and that adapt to prey abundance are likely to have been advantageous. When large prey was less abundant, the possibility of obtaining large numbers of small and medium-sized prey might have contributed to the development of larger, more settled populations as indicated from numerous archaeological finds for the Gravettian hunter-gatherers from Spain to southern Russia (Soffer Reference Soffer, Roebroeks, Mussi and Svoboda2000). This new technology may have also contributed to the diminishing selection pressure for muscularity, vital for large mammal hunting without mechanically delivered projectiles (see Soffer, cited in Pringle Reference Pringle1997).

3.3.1 Hunters Use Many Different Technologies

Almost all studies list more than one technology used, their mix depending on the type of animals hunted and local traditions (Fig. 3.4). This variation is best illustrated by the broad spectrum of how bats are caught and killed. Bats are common wild meat items in Africa and Asia, but are rarely targeted in South and Central America with the exception of one Indigenous tribe, the Nambiquara of Western Brazil, who actively hunt three Phyllostomid bat species for food (Jenkins & Racey Reference Jenkins and Racey2009; Mickleburgh et al. Reference Mickleburgh, Waylen and Racey2009; Setz & Sazima Reference Setz and Sazima1987). Bats are usually hunted either at roosting sites or at feeding sites by a wide variety of methods – bait and hook, bamboo poles with thorns or fish hooks on the end, barbed burrs of some plant species, birdlime, bow and arrow, by hand, catapults and slingshots, fire, firearms including guns, rifles and airguns, funnel traps to catch bats emerging from caves, hand nets, kites with hooks, nylon lines and ropes with hooks, snares, specialized large nets or fishing nets at roost or feeding trees, sticks, stoning and thorny bushes (Mickleburgh et al. Reference Mickleburgh, Waylen and Racey2009).

Figure 3.4 (a) Asurini do Tocantins tribe member from the region between the Xingu and Tocantins rivers holding bow and arrow (WIN-Initiative/The Image Bank Unreleased/Getty Images); (b) Huaorani hunter from Ecuador using blowgun in forest (WIN-Initiative/The Image Bank Unreleased/Getty Images); (c) Bayaka or Aka tribesman holding spear in a forest in the Central African Republic (Timothy Allen/The Image Bank Unreleased/Getty Images); (d) Yangoru Boiken bat catcher retrieves a giant fruit bat from his net in the foothills of Mount Turu, East Sepik Province, Papua New Guinea.

(Timothy Allen/The Image Bank Unreleased/Getty Images)

3.3.2 Techniques Differ between Neighbouring Villages and Regions

Hunting techniques seem to be determined by a mix of tradition, prey species and their densities, but also by the motivations of the hunters themselves. Mbuti Pygmy hunters of the Ituri forest in the Northeastern Congo Basin can be divided according whether they preferentially use bows and arrows or net hunting (Carpaneto & Germi Reference Carpaneto and Germi1989, Reference Aunger1992; Ichikawa Reference Ichikawa1983; Terashima Reference Terashima1983). The use of bows and arrows is the original subsistence hunting strategy of all the Mbuti Pygmies and involves either solitary hunts in which the archer walks in the forest or lies in ambush, and communal beat-hunt hunting, the so-called mota. This Mbuti Efe subgroup in the northeastern parts of the Ituri forest is in social contact with local Sudanic Lese agriculturalists and has adopted iron arrowheads and spear blades from the Lese but never engages in net hunting. The Mbuti Swa use nets alongside bows and arrows. Living in the central, southern and western parts of the Ituri forest, they are in social contact with local Bantu Bira and Ndaka agriculturalists, from whom the Swa have adopted net technology when they invaded the forest about 1,000–3,000 BP.

The impact of the motivation to hunt with different methods is demonstrated by the four different ethnic groups living around the Banyang-Mbo Wildlife Sanctuary in southwestern Cameroon (Willcox & Nambu Reference Willcox and Nambu2007). The Mbo are almost exclusively hunters and gatherers while the Banyangi are hunters, gatherers and also cash-crop farmers. Both groups use shotguns and wire snares at almost the same rate (Banyangi 55% and 37%, respectively; Mbo 56% and 38%, respectively). The Bakossi and Basossi primarily farm cash crops (coffee and cocoa) and do not hunt, but their cash income allows them to buy domestic meat, wild meat and fish. In the oil palm plantation-dominated landscapes of Sumatra motivations and weapon choice are also aligned with the different ethnic groups (Luskin et al. Reference Luskin, Christina, Kelley and Potts2014). Subsistence hunting is predominant in Javanese immigrants and Malay smallholder farmers, who used snare hunting and air rifles to hunt macaques and wild boar for both pest control and consumption. Professional Chinese and Batak hunters specialized in herding wild boar into wire net traps for subsequent sale. Social and cultural reasons are also the motivations for weekly large social day hunts with dogs by ethnic Minangkabau. Finally, wealthy members of a sport hunting group used hunts with firearms from pick-up trucks at night for sport.

The choice of weapon can depend on which prey hunters pursue. For example, Rogan et al. (Reference Rogan, Lindsey and Tambling2017) demonstrates that prey size and weapon choice are significantly correlated with firearms preferred for large game. Optimal foraging theory (Chapter 4) predicts a broad prey profile when a less efficient hunting technology is used compared to a narrower profile for firearms. Indeed, Aché bow hunters’ prey profile is broad and includes less profitable species typically not targeted by shotgun hunters (Alvard, Reference Alvard1993; Hill & Hawkes Reference Hill, Hawkes, Hames and Vickers1983). Although firearm usage is not always correlated with the mean body mass of the target prey (Fa & García Yuste Reference Fa and García Yuste2001; Gonedelé Bi et al. Reference Benítez-López, Alkemade and Schipper2017), the general trend is the focus on large animals, one of the main threats against wildlife in Central Africa (Kümpel Reference Balée and Erickson2006). This is especially problematic for arboreal primates which are preferentially targeted with firearms (Bobo et al. Reference Bobo, Kamgaing, Kamdoum and Dzefack2015; Mittermeier Reference Mittermeier, Marsh and Mittermeier1987). Dounias (Reference Dounias2016) reports that Fang hunters shoot 82% of harvested primate biomass, although firearms contributed 37% of the hunted biomass overall. Traditional weapons may be superior for animals moving in large groups since silent weapons such as blowguns allow the pursuit of several group-members unlike rifles which will invariably disperse the targeted group after hearing the shot (Peres Reference Peres1990). However, shotguns can be used to kill several animals in large dense groups that remain in the same location, for example, the shooting of numerous individual mandrills who will remain on a refuge tree without dispersing, (see Fa and García Yuste (Reference Fa and García Yuste2001).

Prey density can also determine the hunting methods employed. In a study of hunting in two villages by Indigenous Central African foragers, Lupo and Schmitt (Reference Lupo and Schmitt2017) observed that although hunters used the same range of technology there were differences in the frequency of hunting strategies depending on prey density. Hunters from the village in whose area the mean encounter rates with blue duikers, a preferred prey species, was low, would use more individualized technologies such as hand capture, spears and snares. Village hunters from the area with overall high wildlife encounter rates would use nets more often, predominantly targeting blue duikers. In two adjacent Community Hunting Zones in Cameroon, the more densely populated and thus the more heavily hunted zone would be primarily hunted using firearms, providing 79% of the hunted prey, whereas the less densely populated zone was targeted by snares, providing 82% prey (Bobo et al. Reference Bobo, Kamgaing, Kamdoum and Dzefack2015).

3.3.3 Firearms Are the Dominant Hunting Technology Today

Firearms were used in three quarters of the study sites in Table 3.1. Wild animals are hunted with shotguns, rifles, airguns, modern automatic weapons such as the AK47 (Barnett Reference Barnett2000a) and ancient muzzle-loader guns (Barnett Reference Barnett2000a; Martin et al. Reference Arsuaga, Martinez and Arnold2013; Sirén & Wilkie Reference Sirén and Wilkie2016). There is limited information to determine when firearms started being used for hunting in the tropics. In Gabon, guns were traded in the late 1800s, but they only became common in the 1960s (Bernault, 1996, cited in Walters et al. Reference Walters, Schleicher, Hymas and Coad2015). In the Congo Basin, guns were imported from the 1840s onwards, but they did not become widespread until the twentieth century (Savorgnan de Brazza, 1888, cited in Dounias Reference Dounias2016). Technical advances in the mid 1800s, such as the invention of the breech-loading rifle, spread slowly because of the cost and restrictions imposed by the colonial masters. The price of gunpowder also remained prohibitive and delayed the advance of firearms for hunting until the 1930s (Dounias Reference Dounias2016). The subsequent change from black gun powder to the much more powerful smokeless powder improved hunting efficiency substantially as it dramatically increased shooting distance and, thus, outcompeted bows and arrows (Faure, 2002, cited in Dounias Reference Dounias2016). The final technical innovation making firearms highly detrimental for wildlife has been the introduction of flashlights (Dounias Reference Dounias2016), and more recently the even more efficient LED lights (Bowler et al. Reference Bowler, Beirne and Tobler2019). Lighting allows hunting at night, preferred by many hunters (e.g. Ahmadi et al. Reference Ahmadi, Maman and Zoumenou2018; Holmern et al. Reference Holmern, Mkama, Muya and Røskaft2006; Yasuoka et al. Reference Yasuoka, Hirai, Kamgaing, Dzefack, Kamdoum and Bobo2015) because many prey species are more easily detected due to eye reflection of light. Moreover, species such as duikers freeze when targeted by flashlights, making them especially easy prey for night hunters (Yasuoka et al. Reference Yasuoka, Hirai, Kamgaing, Dzefack, Kamdoum and Bobo2015).

Despite the cost of firearms having come down dramatically and the availability of relatively cheap, locally produced weapons, initial purchase and cost of ammunition remains prohibitive for many people in the tropics (Sirén & Wilkie Reference Sirén and Wilkie2016). Gun hunting is the prime activity of soldiers and of wealthier individuals, often from regional cities, such as in Madagascar (Golden Reference Golden2009) and Cameroon (Yasuoka Reference Yasuoka2006b). In many hunter-gatherer societies, gun hunting appears only secondary to snaring because of the higher cost and the greater skill involved (Kümpel Reference Balée and Erickson2006; Kümpel et al. Reference Albertí, Panea and Sañudo2008). This is borne out for most studies on Indigenous Peoples where there is quantitative data (Table 3.1). For example, Baka Pygmy hunters need to sell six duiker carcasses to buy a single rifle cartridge (Yasuoka Reference Yasuoka2006b). None of the Aka Pygmy hunters owned firearms, but most of their non-Pygmy neighbours owned shotguns and sometimes rifles (Kitanishi Reference Kitanishi1995). To overcome the problem of excessive costs of hunting with firearms, three strategies are often adopted. First, many hunters reload their cartridges with locally produced gunpowder (de Mattos Vieira et al. Reference De Mattos Vieira, von Muhlen and Shepard2015) or use muzzle-loaders (Sirén & Wilkie Reference Sirén and Wilkie2016). Second, Baka Pygmy and Aka Pygmy hunters provide services for their richer, non-Pygmy neighbours who provide them with firearms and ammunition in exchange for meat (Duda et al. Reference Duda2017; Kitanishi Reference Kitanishi1995; Yasuoka Reference Yasuoka2006b; Yasuoka et al. Reference Yasuoka, Hirai, Kamgaing, Dzefack, Kamdoum and Bobo2015). Here the main parts of a carcass are kept by the owner of the ammunition, thus making the social relationships between the parties involved also a strong social regulator (Hayashi Reference Hayashi2008). In the case of the Aka Pygmies, the hunter is given the head, neck and internal organs plus two cigarettes (Kitanishi Reference Kitanishi1995). Third, increased market participation can increase cash income and make firearms and ammunition more affordable (Levi et al. Reference Levi, Lu, Yu and Mangel2011a). For those who decide to follow this avenue, the extra cost forces hunters to maximize the amount of meat per shot (Jerozolimski & Peres Reference Jerozolimski and Peres2003), and to provide meat for sale rather than for their own consumption.

There are also social barriers against adopting hunting with firearms, especially amongst hunter-gatherers. Baka Pygmy hunters fear conflicts with the owners and lenders of guns, fear anti-poaching controls, fear the physical risks posed by old weapons and often do not have the required skills to use firearms (Duda Reference Duda2017; Duda et al. Reference Duda2017). On the other hand, firearm hunting bestows high social status. In Baka Pygmy society, shotgun hunters are often considered ‘the best hunters’ (Duda Reference Duda2017). When Baka hunters have access to guns, their success can exceed the success of non-Pygmy hunters dramatically (Fa et al. Reference Bartlett, Williams and Prescott2016). Where poaching carries the risk of detection, such as in protected areas, firearms are generally avoided as gunshots alert ranger patrols to the presence of the hunter (Gandiwa Reference Gandiwa2011). A new development in areas where hunting with firearms is illegal is the replacement of firearms by running prey down with motorbikes or horses and then killing the animals with axes, clubs, spears or machetes to avoid the sound of shots, for example, in Tanzania (Kiffner et al. Reference Kiffner, Kioko and Kissui2014) and Botswana (Rogan et al. Reference Rogan, Lindsey and Tambling2017).

Firearm use in the surveyed studies can vary from none to all hunters using firearms and none to all animals killed with firearms, indicating that a multitude of factors impact gun use. There is a general, but not uniform, trend of increasing gun usage over time. Gill et al. (Reference Gill, Fa, Rowcliffe and Kümpel2012) visited the same site during a period of rapid national economic growth in Equatorial Guinea and reported that hunters using guns increased from 2% in 2003 to 22% by 2010. Percentage of animals taken by shotgun rose over a 14-year period on Bioko Island in Equatorial Guinea (Cronin et al. Reference Cronin, Meñe and Butynski2010). In Cameroon, gun use increased, replacing snares, in both a 15-year study in the Lebialem Division, in the southwest of the country (Wright & Priston Reference Wright and Priston2010) and in three villages near the Dja Biosphere Reserve (southeast Cameroon) between 2003 and 2016 (Ávila et al. Reference Ávila, Tagg and Willie2019).

Gun use differs amongst ethnicities, reflecting changes in socio-economic systems and lifestyle. Shotgun use in Aka Pygmy hunters increased as a percentage of livelihood activities from 5–29% in 1992/3 to 18–56% in 2007/8. By contrast, their farmer-fisher neighbours kept shotgun use at a similar level; 7–29% in 1992/2 and 7–27% in 2007/8 (Riddell Reference Riddell2013). Yasuoka et al. (Reference Yasuoka, Hirai, Kamgaing, Dzefack, Kamdoum and Bobo2015) report on gun use of Konabembe in Cameroon in two adjacent areas and found that at one site 17% of hunters used guns (killing 16% of prey) whilst at a second site 58% of hunters used guns and killed 70% of prey. The two sites differed in their prey density, species composition, forest disturbance, hunting pressure and human density, but it remains unclear what caused the difference in gun use.

In Liberia, ancestral hunting methods have all disappeared and have been replaced by cable snares and shotguns since the civil conflict from 1989 to 2003 (Bene et al. Reference Alvard, Gillespie and Alvard2013). Similarly, civil conflicts which have ravaged the Congo Basin for decades have collapsed many economies and the easy access to firearms may have enabled even more wild meat hunting. In the Amazon Basin, Western contact has led to a rapid change from traditional methods to guns and dogs across all Indigenous societies (Jerozolimski & Peres Reference Jerozolimski and Peres2003). Amongst the Huaorani living in the Yasuní National Park, Ecuador, changes in hunting practices were reported in Papworth et al. (Reference Papworth, Milner-Gulland and Slocombe2013b). The only two South American studies that did not record the use of firearms were both from the 1980s and are for the Huaorani in Ecuador (Rival Reference Rival, Pescola and Palsson2003; Yost & Kelley Reference Yost, Kelley, Hames and Vickers1983). All studies from the 1990s and 2000s reported the use of firearms (Franzen Reference Franzen2006; Lu Reference Lu1999).

There is clear evidence that hunting with guns is much more efficient than hunting with bow and arrow or blowpipes in terms of the number of animals killed at least in the short term. Alvard and Kaplan (Reference Alvard, Kaplan and Stiner1991) compared two Indigenous communities in southeastern Peru, one of which hunted with guns and the other with traditional bow and arrow. Shotgun hunters had relatively short pursuits, averaged 1.3 shots per kill, killed prey often with a single shot, and had uniformly high return rates ranging between 1.2 and 1.5 kg per hour of hunting. In contrast, bow hunters had relatively long pursuits, averaged 30 shots per kill, often missed their target or wounded but did not kill the prey and had low return rates of 0.10 kg per hour of hunting. Wherever there is a mix of modern and traditional hunting technology used, guns attain higher prey kills in study sites in South America (Alvard & Kaplan Reference Alvard, Kaplan and Stiner1991), Africa (e.g. Baka Pygmy hunters, Duda et al. Reference Duda2017) and Asia (e.g. in Arunachal Pradesh, northeast India Aiyadurai et al. Reference Aiyadurai, Singh and Milner-Gulland2010).

The problem with hunting with guns lies in its long-term impact on prey populations if commercial hunting is the main aim. Guns allow the killing of many more animals in a shorter time than traditional hunting methods. When prey is hunted for hunters’ own consumption only, the increased efficiency afforded by guns reduces the required time for subsistence hunting and can allow hunters to reinvest spare time in other activities. When prey is being sold, however, the time saved can be invested in killing more animals. When animals and prey are not privately but communally owned, the Tragedy of the Commons dictates that as many animals as possible should be killed, leading to severe overhunting and unsustainability (Chapters 4 and 5).

3.3.4 Modern Snares Are the Second Most Utilized Hunting Technology Globally

Traditional snares are encountered rarely, with only five study sites reporting snares made of vines, mostly from the last century (Carpaneto & Germi Reference Carpaneto and Germi1989; Dounias Reference Dounias2016; Fa et al. Reference Bartlett, Williams and Prescott2016; Kitanishi Reference Kitanishi1995; Tessmann, Reference Tessmann1913a). Modern cable snares were used in 57% of study sites. Snare hunting is rare in the Neotropics, where only 2 out of 20 study sites listed them as a hunting technique, compared to 75% in Asia and 68% in Africa. Although snares appear to be a major cause of prey declines across tropical Asia, information on snare hunting is still sketchy (Gray et al. Reference Fiedel and Haynes2018; Harrison et al. Reference Harrison, Sreekar and Brodie2016). Their relative absence in the Neotropics might be related to the generally lower prey population densities of forest mammals, making snares comparatively unprofitable (Fa & Purvis Reference Fa and Purvis1997; Peres Reference Peres2000). However, although snares are illegal in most countries in Africa, they still account for most prey killed, as well as biomass, compared to firearms (Fa & Peres Reference Fa, Peres, Reynolds, Mace, Redford and Robinson2001). Their popularity is based on the fact that the material used, wire or nylon cord (Fig. 3.5), is easy to obtain, inexpensive, durable and strong enough for larger animals. Snares can be set under cover of darkness and their low detectability makes them a prime choice for poachers (Gandiwa Reference Gandiwa2011; Knapp Reference Knapp2012; Lindsey et al. Reference Lindsey, Romañach, Tambling, Chartier and Groom2011b). Snare hunting also requires relatively little skill compared to guns, but experienced hunters may be much more successful than inexperienced ones (Kümpel Reference Balée and Erickson2006). In some cases, wire can be stolen from wildlife and domestic fences, as in the Savé Valley Conservancy in Kenya, where rangers removed almost 85,000 snares, all of which were thought to have been made from the perimeter fence (Lindsey et al. Reference Lindsey, Balme and Becker2015). In Zimbabwe, stolen telephone copper cables and steel wire from a veterinary fence along a National Park have been used (Gandiwa Reference Gandiwa2011).

Figure 3.5 Blue duiker caught using nylon rope snares in Bioko Island, Equatorial Guinea.

(photo: M. Grande-Vega)

As for firearms, snares have become more popular over time. Wire cable was introduced in Cameroon after the Second World War and has almost totally replaced vegetal fibre, which rots with moisture, or elephant hair that is only suitable for small prey, although snares made of rattan are still used for small prey (Dounias Reference Dounias2016). As a result, the Fang in Cameroon have changed from more traditional methods to focus on snares, now accounting for 54% of the hunted prey biomass (Dounias Reference Dounias2016). Traditionally, Baka Pygmies used mainly spears for hunting (Bahuchet Reference Bahuchet1992), but wire snares were introduced in the 1960s after contact with neighbouring cultivators to replace traditional, plant-based snares (Hayashi Reference Hayashi2008; Yasuoka Reference Yasuoka2006b; Yasuoka et al. Reference Yasuoka, Hirai, Kamgaing, Dzefack, Kamdoum and Bobo2015). Nowadays, cable snares are the most common hunting technique amongst Pygmy hunters including Baka since this allows for a larger number of captures, therefore suitable for commercial wild meat production (Hayashi Reference Hayashi2008; Noss Reference Noss, Robinson and Bennett2000).

Snares are typically set, left unsupervised and then checked periodically (Fig. 3.5). The passive nature of snaring allows farmers to set and check snares in and at the margin of their fields. Their passive nature can result in indiscriminate capture of animals (Becker et al. Reference Becker, McRobb and Watson2013; MacMillan & Nguyen Reference MacMillan and Nguyen2014) although relatively targeted setting of snares is possible (Coad Reference Coad2007). The non-selectiveness is demonstrated by sex ratios of 1:1 in any captured species as predicted in a study in Equatorial Guinea (Fa & García Yuste Reference Fa and García Yuste2001). Although daily checks are desirable from an animal welfare point of view, longer periods appear to be the norm rather than the exception. For example, Baka hunters checked snares on average every three days (Yasuoka et al. Reference Yasuoka, Hirai, Kamgaing, Dzefack, Kamdoum and Bobo2015). The consequence of leaving snares unchecked or checking these sporadically can lead to significant animal welfare issues and loss of carcasses. But even when checked regularly, animals may suffer from injury and stress. Up to a quarter of total captures can be lost to scavengers and decomposition (Noss Reference Noss1998b), and around one third of animals can escape with injury (Lindsey et al. Reference Lindsey, Romañach, Tambling, Chartier and Groom2011b). In Zimbabwe, 59% of snared animals were found rotten or scavenged, 27% recovered by scouts and only 14% were extracted by poachers out of the 2,398 animals recorded as killed in snares from August 2005 to July 2009 (Lindsey et al. Reference Lindsey, Romañach, Tambling, Chartier and Groom2011b). In hunting zones around a study village in the Dja Biosphere Reserve in Cameroon, snare density was inversely related to distance from the village, but despite a 64% lower snare density in the farthest hunting zone compared to the closest zone, overall capture rate was four times higher and the number of rotting carcasses three times greater in the farthest zone (Muchaal & Ngandjui Reference Muchaal and Ngandjui1999). Dobson et al. (Reference Dobson, Milner-Gulland, Ingram and Keane2019) modelled the amount of usable harvest when 20 snares are checked daily versus only once over a 30-day snaring period to find a three-fold increase for the daily-check scenario.

Two main categories of snares exist – foot snares and neck snares, – whereby the latter constitute the vast majority (Kümpel et al. Reference Alves, Mendonça, Confessor, Vieira and Lopez2009; Noss Reference Noss, Robinson and Bennett2000; Yasuoka et al. Reference Yasuoka, Hirai, Kamgaing, Dzefack, Kamdoum and Bobo2015). When animals are entangled with their heads in neck snares, they are normally strangled to death. Larger animals can be caught by their feet in neck snares. After an animal steps into a typical foot snares, a bent rod springs loose, causing a wire fastened to the rod to wrap around the animal’s foot and lift it into the air (Yasuoka et al. Reference Yasuoka, Hirai, Kamgaing, Dzefack, Kamdoum and Bobo2015). Animals larger than those targeted by any type of snare can still be caught but can escape – often with injuries. The two methods are characterized by different prey profiles. For example, in a study in Equatorial Guinea carnivores were only captured in neck snares and rodents solely in foot snares, but a large proportion of duikers were caught in both types though some were also shot (Kümpel et al. Reference Alves, Mendonça, Confessor, Vieira and Lopez2009). Ungulates, rodents and carnivores are relatively more vulnerable to snares than to firearms (Fa & García Yuste Reference Fa and García Yuste2001). Medium-sized mammals are significantly more vulnerable to snaring (Duda et al. Reference Duda2017; Fa et al. Reference Fa, Ryan and Bell2005; Fa & García Yuste Reference Fa and García Yuste2001; Noss Reference Noss1998b). Rodents, for example, represented 92% of snared animals in southeastern Cameroon (Bobo et al. Reference Bobo, Kamgaing, Kamdoum and Dzefack2015). A review of 36 tropical moist forests sites in seven countries in West and Central Africa revealed higher harvest rates for snared than for shot species, significantly smaller body size of snared versus shot species, higher extraction rates for terrestrial versus arboreal species, higher extraction rates for fast and medium speed species versus slower ones and higher extraction rates for frugivore–herbivores versus other dietary categories (Fa et al. Reference Fa, Ryan and Bell2005).

Snares are typically set along trails and often in clusters. Densities can vary widely with values of up to 56/km² as reported from Equatorial Guinea (Fa & García Yuste Reference Fa and García Yuste2001). In a private property near the Savé Valley Conservancy in Zimbabwe, 1.16 and 0.68 snares/km² were removed in 1998 and 1999, respectively, but the number increased dramatically to around 90 snares/km² per year from 2005 to 2009 after the settlement of adjacent land (Lindsey et al. Reference Lindsey, Romañach, Tambling, Chartier and Groom2011b). Whilst almost 85,000 snares were detected in a period of eight years in the Savé Valley Conservancy, 170,000 snares were removed from just two protected areas in Vietnam and Cambodia between 2011 and 2015 (Gray et al. Reference Fiedel and Haynes2018). The effects of snaring can be chilling. In Asia and in Africa, snaring is a major contributor to defaunation (Becker et al. Reference Becker, McRobb and Watson2013; Gray et al. Reference Fiedel and Haynes2018; Noss Reference Noss1998b). This not only affects target species but also by-catch. Becker et al. (Reference Becker, McRobb and Watson2013) analysed by-catch data from 1,038 antipoaching patrols in Zambia’s Luangwa valley focusing on savanna elephants and large carnivores, to show that additional mortalities of 32% for elephants, 20% for adult (>4 years) male lions and 14–50% of adult and yearling pack members of African wild dogs were inflicted.

3.3.5 Traditional Hunting Technology Generally Augments Modern Technology Today

In only 15% of sites in Table 3.1 neither firearms nor cable snares were used. This proportion is biased towards traditional hunting methods such as bow and arrow and nets because 11 of the 19 sites in the table stem from a single study on Mbuti Pygmies in the DRC that documented a different mix of hunting technologies at different sites (see Fa et al. Reference Bartlett, Williams and Prescott2016). Here, we introduce the five most important traditional techniques: spears, dogs, bow and arrow, nets and blowpipes.

3.3.5.1 Spears

Spears are the oldest hunting weapons discovered and predate the emergence of modern man. As outlined above (see Section 3.2.1) the 400,000 year old Schöningen spears were likely used for thrusting or hand-thrown at close quarters (Shea Reference Shea2006; Thieme Reference Thieme1997; Fig. 3.6). Virtually all historically known hunter-gatherers used spears but none employed spears alone without projectile weapons (Churchill Reference Churchill and Churchill2014). In an extensive survey of small-scale hunter-gatherer societies across the world, Churchill (Reference Churchill1993) observed that almost all had spears in their arsenal, but only half used them for terrestrial hunting. Other uses include hunting marine mammals, spearing fish, warfare and defence from predators. Most spears are thrusting spears and only some groups in Australia and Tasmania are known to use thin, light spears to hunt wallabies and kangaroos. Excluding these thin spears, the distance when thrown is 5.7 ± 0.9 m (Churchill Reference Churchill1993) or up to 20 m (Milks et al. Reference Milks, Parker and Pope2019), depending on the thrower’s skill. Typical use of thrusting spears is as a dispatching tool after prey has been driven by hunters, with or without accompanying dogs, into a disadvantaged position when using nets, snow drifts or geographical features such as valleys, rocks and swamps, or have been caught in traps. Spears were used as part of pitfall traps, but this technology has been replaced by snaring (Lewis & Phiri Reference Lewis and Phiri1998). The spearthrower, also called the atlatl, is a tool that uses leverage to throw a spear or dart at longer distances with a range of about 40 metres (Churchill Reference Churchill1993). The earliest known example is from the upper Palaeolithic in the Dordogne, France; it is made of reindeer antler and dated approx. 17,500 BP (Cattelain Reference Cattelain1989). As a hunting weapon, it is used for marine mammals and waterfowl in Oceania, the Arctic and part of the Americas, but terrestrial hunting is known only from Australia (Cattelain Reference Cattelain and Knecht1997; Churchill Reference Churchill1993).

Figure 3.6 Spear II. The 2.30 m long spear is shown to the left of an incomplete pelvis of a horse, and the base has been broken off. Inset shows a detail of the tip of spear II. Scale in cm.

(From Thieme Reference Thieme1997; reprinted with permission from Springer Nature.)

Spears have been reported for wild meat hunting in Africa, the Americas and Asia (Table 3.1). In the early twentieth century, spears were extensively used by the Fang during collective hunting expeditions (Tessmann Reference Tessmann1913a). Like weapons of war, spears were richly carved and ornamented, thus expressing a special cultural importance. Elevation into the mythical level was also observed elsewhere, such as the Huaorani in South America. With the advent of firearms, spears were slowly replaced and the Fang do not have spears in their arsenal any longer (Dounias Reference Dounias2016). Today, spears are a Pygmy specialty in the rainforest where non-Pygmy people do not use them, but are also still encountered in Madagascar, Eastern Africa savannas and amongst the San in the Kalahari desert (Dounias Reference Dounias2016; Fa et al. Reference Bartlett, Williams and Prescott2016; Golden Reference Golden2009; Holmern et al. Reference Holmern, Mkama, Muya and Røskaft2006; Ikeya Reference Ikeya1994). Pygmy groups use spears to kill larger and more aggressive mammals like elephants, African buffaloes, bushbucks, gorillas and wild pigs or as a dispatching tool, especially in net hunts and whenever any opportunity arises (Bahuchet Reference Bahuchet1992; Carpaneto & Germi Reference Carpaneto and Germi1989; Hayashi Reference Hayashi2008; Kitanishi Reference Kitanishi1995; Yasuoka Reference Yasuoka2006a).