Hidden in the Angolan Highlands is a purportedly new kind of elephant. Conservationist and ornithologist Steve Boyes has spent years tracking this hard-to-find herd, and his expedition is the focus of Ghost Elephants, an eerie, evocative documentary directed by Werner Herzog. The film premiered at the Venice International Film Festival last summer and is now headed to National Geographic and Disney+.

An ornithologist searching for distant pachyderms might seem surprising, but for Boyes the link is natural. He grew up in South Africa and longed to be an explorer, inspired by the people he read about every month in National Geographic magazine. “I grew up waiting for the magazine to arrive; I wanted the maps,” Boyes told Ars. “Those would become my garden, or the field beyond, or the river—wild places imagined and real.”

Boyes’ parents often took him and his brother into wild places, including trips to Botswana and Tanzania. “We used to embed ourselves in baboon troops and walk with impalas,” said Boyes, and while his brother feared elephants, Boyes was comfortable around them from an early age. Ghost Elephants includes beautiful underwater sequences of elephant feet moving through water and of elephants swimming on their sides, scenes that reflect Boyes’ own encounters. Under the right conditions, if they don’t feel threatened, elephants “will come and swim around you and with you and interact with you,” he said. “So elephants have always fascinated me.”

As an adult, Boyes carried out his PhD work on the Meyer’s parrot in the Okavango Delta, which hosts the largest elephant population on Earth. The parrots and elephants had a kind of reciprocal relationship. “Every tree that the parrots were feeding on, the elephants were feeding on,” he said. “The elephants were creating the nest cavities for the parrots by disturbing the trees.”

One feature set S. mirabilis apart from S. aegyptiacus. The name “mirabilis” is Latin for “astonishing.” What Sereno’s team found so astonishing was the large crest crowning the animal’s head, among the biggest ever found.

The scimitar crown

Rather than the knobby, fluted ridge of S. aegyptiacus, S. mirabilis carried a blade-like, scimitar-shaped bony crest that rose and swept back from the snout, peaking high above the eyes. This feature was made of solid bone, unlike the highly porous, pneumatic casques of some living birds. Still, the bone was marked by fine longitudinal striations and deep grooves, showing the bony core served mainly as a foundation.

The recently unearthed skull beside a reconstruction of how its spike may have appeared in life.

In life, the crest of S. mirabilis would have been covered and greatly extended by a keratinous sheath, much like the colorful growth seen in modern helmeted guinea fowls. Scaled to a full adult, the bony core alone would have been roughly 40 centimeters long; with the keratinous covering it might easily have topped half a meter. For Sereno, the role of this “astonishing” scimitar crown was akin to the crests of cranes and herons. “It was asymmetrical. It varied between individuals. So, I think it was solely for display,” Sereno explains.

His team proposes that visual signaling was the main function of both the cranial crests and the huge trunk and tail sails that characterize spinosaurids. Along crowded shorelines and riverbanks, a tall, brightly colored crest or sail would be an effective way to advertise size, maturity and genetic quality to rivals and potential mates without resorting to costly fights.

Still, when it came down to it, S. mirabilis, tipping the scales at well over 7 tons, could certainly brawl. “The Spinosaurus was enormous. I think it could have eaten anything it wanted even though its mainstay was fish,” Sereno says.

Crocodile jaw

Aside from the forehead ornament, S. mirabilis was a highly specialized predator. Its snout was low and with parallel upper and lower margins, ending in a mushroom-shaped expansion at the tip. The upper and lower teeth interlocked precisely—there was a distinct diastema, a gap in the upper tooth row, that accommodated the large lower teeth. The jaw anatomy resembles that of modern long-snouted crocodilians, suited to snatching aquatic prey with a swift, trap-like snap. Interestingly, S. mirabilis had wider spacing between teeth in the rear half of the snout than S. aegyptiacus, despite being otherwise very similar.

You might assume NASA would turn to commercial partners for a fix. United Launch Alliance was already working on a stronger upper stage for Vulcan, the Centaur V, which used the same propellant as the SLS core, and Blue Origin was developing a hydrogen‑fueled BE-3U upper‑stage engine. Those alternatives were less expensive, ready or close to ready, and yet … promptly dismissed.

A decade, billions spent, and little to show

Congress, eager to protect and create jobs, pushed NASA to build an all‑new upper stage. In 2016 lawmakers set aside $85 million for initial design work and have since obligated more than $3.5 billion.

To produce what is essentially a rocket’s second stage.

Using RL‑10 engines that have been flying in space for roughly sixty years.

And after ten years, the new upper stage is still several years away from a first flight.

In many respects the Exploration Upper Stage proved ideal for pork‑barrel spending. It directed contracts to Boeing and Aerojet Rocketdyne (for the engines) and required the construction of a huge new launch tower in Florida — a win for Kennedy Space Center’s Exploration Ground Systems program.

Those initial price tags are worth revisiting. Boeing’s original contract to build the Exploration Upper Stage began at $962 million, and NASA had hoped to fly the vehicle on SLS’s second launch in 2021. That timeline slipped. The launch tower was first estimated at $383 million but more recently was creeping past $2 billion. So we’re talking multiple billions of dollars for a comparatively simple upper stage that uses off‑the‑shelf engines and a very large launch tower.

Planet Labs, a major commercial satellite-imaging firm, said Friday it is pausing the release of imagery for certain parts of the Middle East as the regional conflict moves into its second week.

The company, known as Planet, runs a constellation of several hundred Earth-observing satellites intended to capture views of every landmass on the planet at least once per day. Its clients include think tanks, NGOs, academic institutions, news organizations, and commercial users in agriculture, forestry, and energy, among others.

Planet also holds profitable contracts supplying overhead imagery to the US military and US government intelligence agencies.

“In reaction to the conflict in the Middle East, Planet is imposing temporary restrictions on data access within specific areas of the affected region,” Planet said in a statement emailed to Ars. “Effective immediately, all new imagery collected over the Gulf States, Iraq, Kuwait, and adjacent conflict zones will be subject to a mandatory 96-hour delay before it is made available in our archive.”

Imagery over Iran will continue to be available immediately after acquisition, the company said. “This change applies to all users except authorized government users who maintain immediate access for mission-critical operations.”

Infographic composed of satellite photos depicting damage at a selection of four US military sites, or locations hosting US personnel, in the Middle East following Iranian strikes since February 28, 2026, using images from Planet Labs.

Credit:
Graphic by Nalini Lepetit-Chella and Sabrina Blanchard/AFP via Getty Images)/© 2026 Planet Labs/AFP

Overhead intelligence

In recent days, Planet’s satellite imagery has revealed the aftermath of Iranian missile and drone strikes on US and allied bases in the region, including damage to the US Fifth Fleet headquarters in Bahrain and to a $1 billion US-built early-warning radar in Qatar used to track incoming projectiles. Planet said it aims to prevent “adversarial actors” from using its data for “Battle Damage Assessment (BDA)” purposes. In short, the company does not want to assist Iran’s military in determining where it succeeded or where it failed.