News Science Mystery of the Ancient Nazca Spiral Holes May Be Solved By Michael d'Estries Michael d'Estries LinkedIn Twitter Writer State University of New York at Geneseo Quaestrom School of Business, Boston University (2022) Michael d’Estries is a co-founder of the green celebrity blog Ecorazzi. He has been writing about culture, science, and sustainability since 2005. His work has appeared on Business Insider, CNN, and Forbes. Learn about our editorial process Updated March 9, 2018 05:38PM EST Researchers studying the wells discovered that their spiral design helped funnel wind into the subterranean aqueducts. . (Photo: Creative Commons) Share Twitter Pinterest Email News Environment Business & Policy Science Animals Home & Design Current Events Treehugger Voices Some 2,000 years ago, in a coastal region of Peru that receives less than 4 millimeters of rain annually, an ancient civilization flourished around an agriculture economy that included maize, squash, yucca and other crops. Called the Nazca, their legacy today is best known to the world from the Nazca Lines, ancient geoglyphs in the desert that range from simple lines to image of monkeys, fish and lizards. While the lines are theorized to have been created for religious purposes, the Nazcas' intricate engineering of subterranean aqueducts was the life force that supported their entire civilization. The system tapped into naturally occurring underground reservoirs at the base of the Nazca mountains, using a series of horizontal trenches to funnel the water on its way to the sea. Dotting the surface of these underground aqueducts were dozens, perhaps even hundreds, of spiral-shaped wells known as puquios. Thirty-six of these unique structures still exist today, with many still serving as a source of fresh water for the local population. While the puquios have long been theorized as dual-purpose shafts for both cleaning debris from the tunnels and accessing water, their unique spiral design has remained something of a puzzle. According to Italian researchers at the Institute of Methodologies for Environmental Analysis, that mystery may have been solved thanks to an in-depth analysis of the puquios' layout from satellite imagery. The corkscrew vertical shafts weren't just wells, they surmise, but a sophisticated hydraulic system. Their structure pulled air down into the underground aqueduct system. "... the wind actually helped to push the water through the system, which meant they served as ancient pumps," explains Phys.org. "Exploiting an inexhaustible water supply throughout the year the puquio system contributed to an intensive agriculture of the valleys in one of the most arid places in the world," researcher Rosa Lasaponara told the BBC. “The puquios were the most ambitious hydraulic project in the Nasca area and made water available for the whole year, not only for agriculture and irrigation but also for domestic needs.” Puquios like these dot the landscape along the subterranean aqueducts built by the ancient Nazcas. (Photo: Getty Images) "What is really impressive is the great efforts, organization and cooperation required for their construction and regular maintenance,” added Lasaponara. The work of Lasaponara and others will be published in "The Ancient Nasca World: New Insights from Science and Archaeology," which is a deep dive into Nasca culture from a scientific and archeological perspective. (You can read some of the chapters in the book here.) The Nazca's command over water and subsequent abundance of crops may have led to their eventual demise. U.K. researchers in 2009 studying the region discovered that the Nazca cleared massive swaths of native forest for crops. Particularly devastating was the felling of the huarango tree, a critical piece of the ecosystem that helped soil retain moisture, fertility and shored up vital irrigation channels. Once gone, the entire valley became vulnerable to massive weather events, soil-stripping winds and flooding. "The mistakes of prehistory offer us important lessons for our management of fragile, arid areas in the present," said co-author Oliver Whaley of the Royal Botanic Gardens in Kew, England.