Archeologists believe they have discovered how Egypt’s great pyramids were built

The Great Pyramid is composed of over 2.3 million blocks of limestone and granite, each weighing a staggering two tons.

[Nov. 18, 2023: JD Shavit, The Brighter Side of News]

How did a civilization, without the technology we have today, move colossal stone slabs across vast distances to create these architectural wonders? (CREDIT: Getty Images)

The construction of the Egyptian pyramids remains one of history's most enduring mysteries. For centuries, both historians and the general public have pondered the question: how did a civilization, without the technology we have today, move colossal stone slabs across vast distances to create these architectural wonders?

However, recent findings by a group of archaeologists may shed some light on the conundrum. Delving deep into the lands surrounding the Great Pyramid of Giza, the team embarked on a quest to validate a theory about how the ancient Egyptians might have achieved this remarkable feat.

To grasp the magnitude of the challenge, consider this: The Great Pyramid is composed of over 2.3 million blocks of limestone and granite, each weighing a staggering two tons. "It's a task that even today would require significant resources and engineering expertise," says Dr. Laila Hassan, a leading archaeologist. So, how did the ancient Egyptians do it?

One intriguing clue might come from the environment itself. The research team, through an in-depth analysis of the surrounding area, posits that the Egyptians cleverly utilized the waterways around them, specifically a tributary of the Nile, to transport the massive stones to the desert.


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To validate this hypothesis, researchers first had to obtain and study ancient soil samples from the Giza floodplain. This necessitated digging an impressive 9 metres (30 feet) deep, where they unearthed five fossilized soil samples. These samples were promptly dispatched to a sophisticated laboratory in France for comprehensive analysis.

The goal? To look for signs of ancient pollen and vegetation native to the Nile, evidence that would confirm the presence of an erstwhile waterway. Their persistence was rewarded when the analysis pinpointed traces of the Khufu Branch, an ancient tributary believed to have dried up in 600 BC.

A study published in the journal Proceedings of the National Academy of Sciences states that the former waterscape and higher river levels around 4,500 years ago facilitated the construction of the Giza Pyramid Complex.

Not only did this discovery confirm the existence of the tributary, but it also bolstered the theory that it was instrumental in transporting the stone slabs that would later become an integral part of the pyramid's construction.

The pyramids at Giza have puzzled historians for centuries. (CREDIT: Edwin Remsberg/VWPics/Universal Images Group/Getty Images)

Moreover, the meticulous research unearthed a biodiversity hotspot. The team identified an astounding 61 species of plants during their analysis, providing a richer picture of the ancient Egyptian landscape.

Environmental geographer Hader Sheisha, who was part of the research group, articulated the significance of this find. "Without this tributary," Sheisha explained, "it would have been virtually impossible to build the pyramids. It acted as a natural conveyor belt, easing the logistical nightmare of moving such enormous stone blocks."

Location of the cores on the Giza floodplain. The two cores used to reconstruct Holocene variations in Khufu-branch levels (cores G1 and G4) are located where the Khufu basin was connected to the Nile. The Giza Pyramid Complex currently lies >7 km from the present-day Nile branch. (CREDIT: PNAS)

The spark that ignited this groundbreaking research was a fascinating piece of papyrus discovered in the Red Sea. This historical document detailed the account of an officer named 'Merer', who was tasked with transporting limestone up the Nile to a construction site in Giza.

When Sheisha was introduced to the papyrus, it immediately caught her attention. “I was so interested because this confirms that the transport of the pyramid’s building materials were moved over water,” she revealed in an interview with The New York Times. "Understanding more about the environment and infrastructure of that time can help decode the perplexing enigma of the pyramid’s construction,” she emphasized.

Reconstructed Khufu-branch variations of the Nile during the last 8,000 y. Pollen-derived Khufu-branch levels (K-1, blue line) expressed as Loess smoothing scores (with 2.5 and 97.5 percentiles) compared with Nile Delta sedimentation rates (red line). (CREDIT: PNAS)

The revelation that the ancient Egyptians may have used a network of natural waterways to facilitate the movement of the pyramid's construction materials is a testament to their ingenuity. It not only provides a plausible explanation for the construction of these wonders but also offers a captivating glimpse into the resourcefulness and adaptability of this ancient civilization.

As modern technology and techniques continue to intersect with ancient history, it's exciting to think about what other mysteries we might unravel next. For now, though, we have a tantalizing glimpse into how the Egyptians might have accomplished one of the greatest architectural feats in human history.


Note: Materials provided above by The Brighter Side of News. Content may be edited for style and length.

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Joshua Shavit
Joshua ShavitScience and Good News Writer
Joshua Shavit is a bright and enthusiastic 18-year-old with a passion for sharing positive stories that uplift and inspire. With a flair for writing and a deep appreciation for the beauty of human kindness, Joshua has embarked on a journey to spotlight the good news that happens around the world daily. His youthful perspective and genuine interest in spreading positivity make him a promising writer and co-founder at The Brighter Side of News. He is currently working towards a Bachelor of Science in Business Administration at the University of California, Berkeley.