Kayak assembly necessarily starts with the two gunwales, which are the primary structural components around which everything else is built. Gunwales determine the symmetry of the hull; they constitute the bulk of its length and also determine the sheer (profiled curvature of the deck). The gunwales essentially hold the kayak together through tension. They are bound at each end and then are forced apart in the middle, thus creating pressure that holds the frame together in the middle (Figures 2 and 3). Kayaks are subject to many different stresses during normal operation: the weight of the hunters themselves; sudden movements during stalking and striking of animals; and the impact of waves as the craft moves through the water. Gunwales must be the strongest part of the kayak, and the natural grain of the wood must stretch longitudinally from tip to tip. Weak points exist where the grain intersects the sides of the gunwale, and these places will snap first when enough pressure is applied (Figure 3). A gunwale damaged in this way could have catastrophic consequences, as the frame would simply collapse under the kayaker’s weight and the external water pressure.

The most critical stage of kayak construction, at least in terms of wood selection, is ensuring that both gunwales are exactly the same strength and will bend equally. If one gunwale strake is stronger than the other, it will impact the symmetry of the kayak and cause the shape to be straighter on one side than on the other. Asymmetry affects navigation, as the hull will not follow a straight path through the water (Figure 4); the kayaker will constantly have to correct the course, thus interfering with the functionality of the kayak in a number of ways. This is a serious shortcoming, since Inuit hunters at times travelled hundreds of kilometres over water. Additionally, a symmetrical hull is a necessity for most forms of hunting, from seal harpooning to caribou lancing, because the hunter has to make as little noise as possible. In general, the hunter has to line the kayak up in the right direction and silently paddle a few strokes to within striking range. Such a silent approach would be compromised by any course corrections due to an asymmetrical hull (e.g., Nansen 1893).

Equalising the gunwales to make them symmetrical requires not only special carpentry skills, but also the right material. One must choose long pieces of wood that have as straight a grain as possible—any natural twisting, common to most pieces of wood, will affect the way that the gunwales bend when drawn apart. The ideal material for a gunwale is a single piece, long and straight enough, with as few knots as possible; ideally, both gunwales should be made by splitting a single piece into two pieces that are equally strong because they share the same internal structure (Arima 1975: 110-111; Petersen 1986: 22).

In many parts of the Arctic, it is extremely rare to find driftwood of the quality and length to make gunwales out of a single piece (Alix 2009; Grønnow 1996). Many kayaks collected from around the Arctic have gunwales that are assembled from multiple pieces, which are scarfed together by a variety of different joints. Figure 5 shows several examples of scarfed gunwales, including three from different archaeological contexts in Greenland. In all cases, each gunwale segment has very straight grain, even though the pieces are not long enough to span the entire length of the kayak. Scarf joints were probably the primary way of building gunwales before wood became available commercially. Wherever ideal pieces of driftwood were unavailable, or wherever scarfing was preferred to achieve a specific form, builders evaluated different pieces in terms of their compatibility with each other and how they could be assembled and bound together.

Once the two gunwales have been matched to form a symmetrical outline, they are held in the desired shape by crosspieces (Figures 2 and 6). Crosspieces have to be securely attached to the gunwales so that they can hold the gunwales in the correct position and will not loosen during normal operation. Crosspieces also have to be shaped and fitted well enough to prevent creaking that would compromise stalking of prey as the kayak moves. For this, a number of different techniques can be used. Mortises can be made in the gunwales, and carved crosspieces placed into them in a locking position. Other strategies employ a more flexible joint where the crosspiece is mortised only halfway and is lashed into place using a variety of materials such as bearded sealskin line and braided sinew. The archaeological examples in Figure 5 show mortises cut only partially into the gunwale, whereas in many examples the joints are fully locked (Petersen 1986). In either case, when carving into the gunwales, the builder has to carve perpendicular to the grain to form a mortise so that the crosspiece can be tightly placed. Again, gunwales need to have a straight grain, as mortises further weaken the frame, and such weakening is especially problematic where the grain “runs out” of the strake (Figure 3).

Many different kayak types include crosspieces that are cambered to raise the deck above the gunwales. In most Bering Strait and Aleutian types, the entire length of the deck is raised, and all of the crosspieces arched. For most Eastern Arctic types, the deck is only elevated immediately forward of the cockpit, to provide enough room for the kayaker’s legs. In Eastern Arctic kayaks, the first crosspiece in front of the cockpit is usually called the masik, the same word for the gill of a fish (Arima 1975: 108). The masik must be curved, and strong enough to take the weight of a hunter’s body entering the kayak (Figure 2). Curved deck pieces must follow the desired arc shape, while being robust enough to withstand a variety of forces. Such deck pieces tend to be made from naturally curved wood. In the first two crosspieces visible in Figure 6 (a and b), the grain follows the curvature to both ends of the piece. Zimmerly’s (1979: 4-6) ethnographic depiction of Hooper Bay kayak construction also shows the builder (Dick Bunyan) making crosspieces out of wood from a tree stump, where the grain runs from the trunk to the root at a point where it matches the desired shape (see also Andrew 2008: 244-298).

The gunwales and the crosspieces together form the top deck and determine the dimensions of the hull from a top-down perspective, but not its cross section. The ribs span the distance between the gunwales, thus determining its depth and shape at any particular cross section (Figures 2 and 6). Together with the placement of the stringers, the ribs determine the volume of the hull, as well as many performance characteristics, such as manoeuvrability and stability. Different hull types vary considerably in their number of ribs, but all of these designs share the basic requirement of collectively supporting the kayaker’s weight, and the pressures the ribs exert during operation (e.g., during rolling). Because of the shape of the gunwales, no two ribs in a kayak are exactly the same shape or size, and each rib must be individually tailored to create the desired hull.

Unlike the cambered crosspieces, the arc of the ribs is usually too extreme for one to find pieces of driftwood that naturally have the desired grain curvature. A number of techniques can be used to bend the ribs permanently into the required shape, mostly by some variation of soaking, heating, steaming, and clamping the inside curve of preformed pieces—often using the builder’s teeth (Petersen 1986; Zimmerly 1979). In order for the wood to bend without snapping, the grain needs to be perfectly straight without intersecting the sides. Even if a rib with an angled grain does not break while being bent into shape, it will remain a weak point of the frame and be prone to snapping during operation (Figure 7). While broken ribs are not as critical a problem as broken gunwales, they can stick out into the skin, causing asymmetry in the hull shape. The ribs are generally mortised securely into the gunwales as depicted in Figure 5. As with wood selection for the gunwales, a straight grain is necessary, but the small size makes it possible to use several alternatives to driftwood. For example, in Greenland, it was very common to use locally available dwarf birch (Betula nana) and willow (Salix arctica)—referred to as orpik in Table 1 (Petersen 1986).

Once the ribs are securely mortised or lashed to the gunwales, they provide a platform for several stringers and often a keel, all of which act as the resting points for the skin rather than the ribs themselves (Figures 1, 2, and 6). The positioning of the stringers changes the points at which the skin covering touches the frame, thus changing the shape of the hull and its stability. The number of stringers used in a frame is quite variable; in general, the rounder the hull, the more stringers are required to prevent the skin from resting on the ribs. For example, most Greenlandic hulls only have two stringers and a strong keel; this creates a triangular hull with two extra points of stability (Golden 2006). Other regions have hull shapes that range from perfectly round to perfectly flat (Arima 1975:113; Golden 2006). Although the stringers are essentially bent around an extant frame created by the gunwales, crosspieces, and ribs, they must be strong enough to bear variable pressures during use. As with the gunwales, the stringers need to run the entire length of the kayak and are likewise ideally made from wood that is as straight-grained and knot-free as possible. Stringers, like gunwales, are often composed of different sections (e.g., Bergsland 1991: 179).

For all stages of kayak construction, the wood has to meet certain common criteria. All parts of the frame require wood that is as knot-free and straight-grained as possible—or in the case of cambered crosspieces, wood whose grain already bends naturally in a desired way. Selecting the right wood is key to building symmetrical and structurally sound kayaks. Even where structural components, such as gunwales, had to be assembled from many segments, builders sought pieces that could match each other.