Microblade technology explained

Microblade technology is a period of technological microlith development marked by the creation and use of small stone blades, which are produced by chipping silica-rich stones like chert, quartz, or obsidian. Blades are a specialized type of lithic flake that are at least twice as long as they are wide.[1] An alternate method of defining blades focuses on production features, including parallel lateral edges and dorsal scars, a lack of cortex, a prepared platform with a broad angle, and a proximal bulb of percussion.[2] Microblades are generally less than 50 mm long in their finished state.[3]

History

The geographic origin of microblades is poorly understood, with differing theories posing origins in Southern Siberia, Northern China, or the PHSK (Paleo-Hokkaido-Sakhalin-Kurile) peninsula, with dates ranging from over 30,000 BP to as little as 18,000 BP. The microblade technology has been associated with the Ancient Paleo-Siberians.[4] Because microblade technology is economical (using less raw material than other technologies), relatively easy to make, and extremely portable, it came into widespread use over vast parts of northern Asia and northeastern Siberia during and after the Ice Age. Microblade technology was very efficient for hunting because it used light, barbed spears. During the Ice Age, hunter-gatherers suffered from shortage of food resources, so they had to move more frequently. Microblade is suitable for high mobility and rapid weapon production, as well as reducing failure of hunting and lost or damaged weapons.[5] In other words, in the resource-limited environment of the Last Glacial Maximum, hunter-gatherers invested more time acquiring better raw materials and developing the technique of lithic manufacture.[6] Barbed tips opened wounds and the resulting blood loss killed prey faster and with less loss of hunting equipment than traditional spears.

These changes in lithic technology appear to have been adaptations to reduced resource availability due to climate changes during the Last Glacial Maximum and Younger Dryas allowing for more efficient sustenance strategies. An important site for learning more about the diverse adaptations of the microblade is Shuidonggou Locality 12 (SDG12). It was at this site that microblades were found along with diverse artifacts: needles, awls, and a bone knife handle. This handle is a big indicator that microblades were used for multiple purposes, and no longer were exclusive to hunting.[7] In at least one site in Northern China, microblades are also found in context with heat shattered and burned stone, usually evidence for stone-boiling practices, another resource intensification strategy aimed at recovering more nutrients from food resources via cooking.[8]

The first Native Americans brought this technology with them across the Bering Land Bridge to North America. At least six independent Native American groups used microblade technology, including the Poverty Point/Jaketown, Hopewell culture, Tikal Maya, and Northwest Coast peoples. Specialized craftspeople manufactured millions of microblades in the Mississippian chiefdom of Cahokia, in Illinois,[9] as did Chumash (tribe) craftspeople in California's Northern Channel Islands. In both of these cases, microblades were sharpened to a point and attached to the end of sticks, creating microdrills. These microdrills were used to drill holes in marine shells to create beads. Shell beads were used as money among the Chumash, and as a result microblades were a vital part of the Chumash economy.

See also

Bibliography

Notes and References

  1. Book: Crabtree, Don E. . An introduction to flintworking, (Occasional papers of the Idaho State University Museum, no. 28) . Pocatello, Idaho . Idaho State University Museum . 1972.
  2. Book: Johnson, Jay K. . Poverty Point Period Blade Technology in the Yazoo Basin, Mississippi . Lithic Technology . 1983.
  3. Book: Arnold, Jeanne E. . Craft Specialization in the Prehistoric Channel Islands, California . Berkeley, California . University of California Press . 1987.
  4. Mao . Xiaowei . Zhang . Hucai . Qiao . Shiyu . Liu . Yichen . Chang . Fengqin . Xie . Ping . Zhang . Ming . Wang . Tianyi . Li . Mian . Cao . Peng . Yang . Ruowei . Liu . Feng . Dai . Qingyan . Feng . Xiaotian . Ping . Wanjing . June 2021 . The deep population history of northern East Asia from the Late Pleistocene to the Holocene . Cell . 184 . 12 . 3256–3266.e13 . 10.1016/j.cell.2021.04.040 . 0092-8674. free . 34048699 .
  5. Yi. Mingjie. Bettinger. Robert L.. Chen. Fuyou. Pei. Shuwen. Gao. Xing. The significance of Shuidonggou Locality 12 to studies of hunter-gatherer adaptive strategies in North China during the Late Pleistocene . Quaternary International. 2014. 347. 97–104. 10.1016/j.quaint.2014.04.009. 2014QuInt.347...97Y.
  6. Mackay. A. Marwick. B. Costs and benefits in technological decision making under variable conditions: examples from the late Pleistocene in southern Africa. Keeping Your Edge: Recent Approaches to the Organisation of Stone Artefact Technology. BAR=S2273. 2011.
  7. Yi. Mingjie. Bettinger. Robert L.. Chen. Fuyou. Pei. Shuwen. Gao. Xing. The significance of Shuidonggou Locality 12 to studies of hunter-gatherer adaptive strategies in North China during the Late Pleistocene . Quaternary International. 2014. 347. 97–104. 10.1016/j.quaint.2014.04.009. 2014QuInt.347...97Y.
  8. Yi. Mingjie. Bettinger. Robert L.. Chen. Fuyou. Pei. Shuwen. Gao. Xing. The significance of Shuidonggou Locality 12 to studies of hunter-gatherer adaptive strategies in North China during the Late Pleistocene. Quaternary International. 2014. 347. 97–104. 10.1016/j.quaint.2014.04.009. 2014QuInt.347...97Y.
  9. Book: Yerkes, Richard W. . Microwear, Microdrills, and Mississippian Craft Specialization . Society for American Archaeology.