Introduction
Metallurgy in North America may have begun as early as 7,000 years ago1,2. By the Middle and Late Archaic periods between 6000 and 3000 B.P. a florescence of copper working, known as the Old Copper Culture, thrived in and around the world’s largest naturally occurring pure copper deposit which is in North America’s Lake Superior region3. During these millennia, hunter-gatherers stretching from central Canada to the eastern Great Lakes regularly made utilitarian implements out of copper4,5,6,7,8,9,10,11,12, only for these items to decline in prominence and frequency as populations grew and social complexity increased during the Archaic to Woodland Transition1,13,14,15,16,17. After 3000 B.P. prehistoric people in Eastern North America continued to use copper, but it was mostly relegated toward ritualized items16,18.
Binford19 referred to this decline in utilitarian tools made from copper as the Old Copper Culture “technomic devolution”, and it is a unique event in archaeologists’ global understanding of prehistoric metallurgic evolution20. While the use of stone implements often continued into the metal ages21, analogous ones produced from metal ultimately replaced these implements. Indeed, the near-global transition from stone to metal tools during the early- and mid-Holocene appears to be a ubiquitous, unidirectional transition22,23,24,25,26. Cases where metal tools were indigenously innovated and used, but did not ultimately predominate or replace stone tools, are rare. Thus, the abandonment of Old Copper Culture utilitarian tools facilitates the examination of an exceptional situation in human prehistory: how and why metal tools were selected against.
Binford19 found this situation particularly “interesting” because of the general assumption that in terms of “absolute efficiency” copper tools were superior to their functional equivalents in stone, possessing both greater durability as well as superiority in accomplishing cutting and piercing tasks. However, acknowledging that the manufacture of copper tools would have required greater energy expenditure than stone tools, Binford19 maintained that copper tools would have still been more efficient in terms of net energy expenditure. This is because copper tools were “probably more durable and could have been utilized for a longer period of time”19. Thus, despite the greater energy required to produce a copper tool relative to a stone one, a copper tool’s durability would have conserved energy in task performance. Binford19 was less certain whether copper tools were superior to stone ones in cutting and piercing functions, suggesting that “only experiments can determine”19 that difference.
Current archaeological evidence is consistent with the hypothesis that population growth and increased social complexity contributed to the selection against utilitarian copper tools around 3000 B.P. Larger, more numerous, and more ostentatious cemeteries during the Late Archaic suggest that populations in the Upper Lakes were growing, and societies were becoming less egalitarian. One clear archaeological signal of increased burial ostentation is the interment of ornamental copper artifacts13,15,19. Thus, it has been argued that an increasingly socially complex world required an increase in ornamental copper production, resulting in a concomitant production decline in utilitarian copper tools14,15,16,17,18,27.
However, whether demographic and social factors alone led to the decline of utilitarian copper tools after 3000 B.P. is currently unknown because experimental tests examining Binford’s19 assumptions regarding copper versus stone tool durability and cutting ability have yet to be conducted. Here, we assess those assumptions with replicas of the implement best suited to test both of these factors simultaneously: knives. We use a mechanical engineering approach that measures the amount of energy expenditure needed to complete a simple task—cutting a uniform substrate—to evaluate whether or not there exist differences in durability and cutting ability between knives made from copper versus those made from stone.
Materials and Methods
Thirty replica copper blades were produced by M.R.B.20. The specimens were suitable in shape for controlled materials testing, but similar in composition and internal structure to those produced during the Late Archaic20 (SI Appendix). The copper used for production of the experimental specimens was procured from same mining area that would have been used in ancient times, the Keweenaw Peninsula, Michigan1,2,28. Thirty stone flakes were produced by A.J.M.K. and M.I.E. from Keokuk chert, a common toolstone used throughout the North American Midwest. Each edge angle of a copper blade specimen corresponded to a similar edge angle of a stone flake specimen (SI Appendix).
Our sharpness and durability cutting experiments follow closely the procedures described in Key et al.29 (SI Appendix). We used an Instron Universal Materials Tester (Model 5967) in which peak force (N) and total work (J) during cutting were calculated for all specimens. Following Schuldt et al.30, force and work are used as proxies for edge sharpness. In lieu of biological tissues, modern mechanical tests of sharpness regularly employ flexible soft solid plastics as the cutting substrate31,32,33. This is due to the structural inconsistencies that exist in the muscle fibers of meat, which ultimately cause variation in the force and energy measurements. Here we use standard PVC (polyvinyl chloride) tubing with 6 mm O.D. cut to length of approximately 15 cm for mounting in the substrate grips.
We conducted three analyses comparing copper versus stone knives: initial sharpness, final sharpness, and durability. To assess initial sharpness, we measured the force and work necessary for the first cut of the substrate before the knives were blunted. To assess final sharpness, we averaged the force and work necessary to cut the substrate for each of the five subsequent cutting tests performed after a blunting event (SI Appendix). The lower force30 and work required for a cut indicated a sharper tool. To assess durability34 (in this case the ability of an edge to resist blunting over time), we used repeated test cuts with the same blade35 to examine how much more force and work was required to cut the substrate for the post-blunting cutting events versus the initial cut. A smaller difference between these two values indicated a more durable material.
The sharpness and durability data were analyzed using IBM SPSS version 23. The nonparametric Mann-Whitney U tests with Monte Carlo permutation (10,000 permutations) and 95% confidence intervals were used for the analyses. Mann-Whitney U is a conservative statistical procedure that requires only minimal assumptions of the data36,37. Effect size r was also calculated37,38. All raw data can be found in Dataset S1.