OREGON COAST: BASALT COLUMNS

FOSSILS OF EGYPT: LIMESTONE AND LIFE

Spinosaurus, Fukui Prefectural Dinosaur Museum

Egypt is often celebrated for its pyramids and pharaohs, but beneath those golden sands lies a much older and equally astonishing legacy — the fossil record of a land that has shifted from lush tropical forests to inland seas and back again.

From the Western Desert to the Fayum Depression and Wadi Al-Hitan (the Valley of the Whales), Egypt’s rocks preserve nearly 100 million years of life on Earth, from the Cretaceous dinosaurs that roamed its river plains to the Eocene whales that swam through the Tethys Ocean.

Over the past few posts, we've looked at the geological wonders of Egypt. Here is a deeper look at some of the many interesting fossil species to be found in this rich paleontological playground.

Petrified Wood — A Forest Turned to Stone

Across Egypt’s deserts, the ground often glitters with fossilized trees. The Petrified Wood Protectorate near New Cairo, along the Cairo–Suez road, and wide stretches of the Western Desert are carpeted in ancient trunks and branches turned to stone.

These fossil forests are vivid evidence that much of Egypt was once a humid, tropical landscape, rich with vegetation. The trees, buried in sediments and permineralized over millions of years, became exquisitely preserved in silica. Today, their polished cross-sections shimmer with bands of reds, browns, and golds — a striking reminder of the region’s deep ecological transformations.

Reptiles of the Fayum — Turtles, Crocodiles, and Giants — The Fayum Depression has yielded a wealth of Eocene reptile fossils that speak of a warm, watery world teeming with life. Land tortoises like Testudo ammon roamed the ancient floodplains, while river turtles such as Podocnemis blanckenhorni and Stereogenys pelomedusa swam through slow-moving channels. 

Even more dramatic are the remains of Gigantophis, one of the largest snakes ever discovered, and Tomistoma, a crocodile-like predator from the Qasr al-Sagha Formation. These reptiles hint at an ecosystem that blended mangroves, lagoons, and river deltas — a mosaic of habitats where both freshwater and marine species thrived.

Birds of an Ancient Delta — The Fayum’s fossil beds also record an impressive diversity of Eocene and Oligocene birdlife. The ancient wetlands once supported ospreys (Pandionidae), flamingos (Phoenicopteridae), herons, cranes (Gruidae), cormorants (Phalacrocoracidae), and even the massive shoebilled stork (Balaenicipitidae).

These avian fossils, comparable to species found today around Lake Victoria and the Upper Nile, suggest a vibrant, subtropical ecosystem rich in lakes and marshes — a far cry from the arid desert we see today.

Mammals of the Fayum — Whales, Elephants, and Early Primates

The mammalian fossils of Egypt are among the most extraordinary in the world. In the Fayum Depression and at Wadi Al-Hitan, paleontologists have uncovered a sweeping record of evolution from land to sea and from primitive mammals to the ancestors of modern species.

At Wadi Al-Hitan, skeletons of early whales — Basilosaurus isis, Dorudon atrox, and Phiomicetus — preserve a pivotal evolutionary moment when whales transitioned from walking on land to swimming in the sea. Their long, streamlined bodies and tiny hind limbs are beautiful testaments to nature’s adaptability.

Meanwhile, the terrestrial Fayum deposits reveal a menagerie of early mammals:

• Arsinoitherium, a massive, rhinoceros-like creature with twin horns;
• Moeritherium, a semi-aquatic ancestor of elephants and manatees;
• Palaeomastodon and Phioma, early proboscideans bridging the gap to modern elephants;
• and Megalohyrax, a giant relative of today’s small hyrax.

Carnivorous mammals also prowled these Eocene landscapes — species like Apterodon, Pterodon, and Hyaenodon, formidable predators of their time.

The Fayum Primates — Our Ancient Cousins — Among the Fayum’s most scientifically valuable discoveries are the fossils of early primates, bridging the gap between ancient prosimians and modern monkeys and apes.

From the lower sequence, we find forms like Oligopithecus savagei and Qatrania wingi, while the upper sequence preserves Catopithecus browni, Proteopithecus sylvia, and the well-known Apidium and Parapithecus species.

Perhaps most famous is Aegyptopithecus zeuxis, a small tree-dwelling primate with forward-facing eyes and a relatively large brain. It is often cited as one of the earliest known ancestors of modern Old World monkeys and apes — and, by extension, of humans.

These fossils from the Jebel Qatrani Formation provide an unparalleled window into primate evolution roughly 35 to 30 million years ago, when Africa’s tropical forests were home to our distant kin.

Dinosaurs of the Cretaceous Desert — Long before the whales and primates, Egypt’s landscape was dominated by Cretaceous dinosaurs. The Bahariya Formation and Nubian Sandstone have yielded fossils of immense sauropods and ferocious theropods, painting a vivid picture of life 95 million years ago.

Among the stars of this ancient cast are:

• The long-necked Aegyptosaurus and Paralititan, massive plant-eating sauropods;
• The sleek, predatory Bahariasaurus, Carcharodontosaurus, and Deltadromeus;
• The semi-aquatic Spinosaurus, with its iconic sail-backed spine — perhaps one of the most famous dinosaurs to ever emerge from African rock; and Mansourasaurus, a titanosaur discovered more recently, helping to link Africa’s late Cretaceous fauna with those of Europe and Asia.

These finds demonstrate that Egypt was once a fertile delta world of rivers and floodplains, where dinosaurs thrived long before the Sahara turned to sand.

Egypt’s Fossil Sites — Portals Through Time — Key fossil localities across the country continue to reveal Egypt’s ancient ecosystems:

• Wadi Al-Hitan — Eocene marine fossils, including whales and sea cows.
• Fayum Depression — rich terrestrial and freshwater deposits with early mammals and primates.
• Bahariya Formation — famous for Cretaceous dinosaurs and early vertebrates.
• Jebel Qatrani Formation — Oligocene primates and proboscideans.
• Qasr el Sagha Formation — reptiles, turtles, and early crocodilians.
• Upper Cretaceous Phosphates and Variegated Shale — marine invertebrates and early fish.
• Moghra Oasis — Miocene fossils bridging the gap between ancient and modern fauna.
• Queseir Formation — Upper Cretaceous (Campanian) deposit in the Kharga oasis of the Southwestern Desert where the first side-necked turtle Khargachelys caironensis can be found

Egypt’s fossils offer a spectacular narrative of evolution, climate, and change — from swampy Cretaceous river deltas to lush Eocene seas and forests, to the deserts we see today. 

Each discovery connects the story of Earth’s deep past with the land of the Pharaohs, revealing that Egypt’s most enduring monuments are not her pyramids, nor her simple blocks of stone, but the fossils buried them

Image Credit: Spinosaurus at the special exhibit of Fukui Prefectural Dinosaur Museum by Palaeotaku CC BY 4.0

TYLOSTOME TUMIDUM

This lovely big fellow is Tylostoma tumidum, an epifaunal grazing Lower Cretaceous Gastropod from the Goodland Formation near Fort Worth, Texas, USA. (171.6 to 58.7 Ma)

PALM TRUNK MOULD

George Mustoe of the Burke Museum preparing to make a mould of a palm trunk that once gew in the wetlands that bordered an ancient river.

ERBENOCHILE ERBENI

A spectacular specimen of the trilobite Erbenochile erbeni. This impressive fossil arthropod shows unusual schizochroal eyes characteristic of the genus.

Family Odontopleuridae, Odontopleurid trilobite from the Lower Devonian, Emsian, 408 to 393 MYA, Bou Tiskaouine Formation, Hamar l”Aghdad Limestones, Taharajat, Oufaten, Djebel Issoumour

ARNIOCERAS AMMONITE: CANADIAN ROCKIES

CAMPING UNDER THE STARS

TRIASSIC PAPER CLAMS FROM PINE PASS NEAR TUMBLER RIDGE

Triassic Paper clams, Pardonet Formation

In the rugged foothills of Pine Pass, near the small northern British Columbia town of Chetwynd, the rocks tell a story from over 200 million years ago—a story written in shell just a short walk from the main road. 

Here, in outcrops of the Pardonet Formation, the remains of once-living bivalves called paper clams—or “flat clams”—paint a vivid picture of life in the Late Triassic seas.

During the Triassic, roughly 237–201 million years ago, these delicate-shelled bivalves of the genus Moinotis, specifically Moinotis subcircularis, thrived in shallow marine environments. 

Their thin, flattened shells resemble wafer-like sheets, earning them the common name “paper clams.” 

Despite their fragile appearance, they were ecologically tough, colonizing vast seafloor regions after the Permian-Triassic mass extinction—Earth’s most catastrophic biodiversity crisis. In the wake of devastation, paper clams became pioneers in new marine ecosystems, spreading widely across the Triassic world.

At Pine Pass, the Pardonet Formation captures this resilience in stone. The strata—composed mainly of silty shales and fine-grained sandstones—represent an ancient seabed deposited along the western margin of Pangea. These rocks are part of the larger Western Canada Sedimentary Basin and are well known for their rich fossil assemblages, including ammonoids, conodonts, and marine reptiles. Yet, among these Triassic relics, it’s the paper clams that often dominate.

A short scramble up the rocky slope near the highway reveals bedding planes glittering with thousands of tiny, overlapping shells. They lie perfectly preserved, their paper-thin forms cemented into the matrix as though frozen in a whisper of time. Each shell records a pulse of ancient life in a warm, shallow sea teeming with invertebrates.

Our field stop at Pine Pass was a spontaneous detour en route to a paleontological conference in nearby Tumbler Ridge—a region equally famed for its dinosaur tracks and marine fossils. What was meant to be a quick roadside break became a fossil feast. 

Within minutes, we were crouched among the rocks, gently tracing our fingers over Moinotis subcircularis—delicate, symmetrical, and as hauntingly beautiful as the day they settled on the Triassic seafloor.

GASTROPODA

LION: PANTHERA LEO

 

PARASAUROLOPHUS WITH A PEARL EARRING

 

ICHTHYOSAUR EVOLUTION

During the early Triassic period, ichthyosaurs evolved from a group of unidentified land reptiles that returned to the sea.

They were particularly abundant in the later Triassic and early Jurassic periods before being replaced as a premier aquatic predator by another marine reptilian group, the Plesiosauria, in the later Jurassic and Cretaceous periods.

KELP FORESTS AND CARBON SINKS

Walk along any rocky beach on the Pacific coast after a storm, and you’ll likely find a treasure trove of kelp washed ashore—long ribbons of glossy brown seaweed, glistening in the sunlight like strands of mermaid hair. 

Some pieces stretch for meters, still tangled with small shells and bits of driftwood, while others hold tight, bulbous floats that once kept them buoyant in the underwater forests just offshore. 

When the tide recedes, the air fills with the unmistakable scent of iodine and salt—an ancient perfume carried by the sea.

Kelp is a brown alga, part of the group Phaeophyceae, which evolved roughly 150 to 200 million years ago. 

While kelp itself doesn’t fossilize easily (it’s soft-bodied and decomposes quickly), its ancient lineage can be traced through molecular and microfossil evidence. The earliest relatives of kelp likely appeared in the Jurassic seas, when dinosaurs ruled the land and the oceans teemed with ammonites. 

Microscopic spores and chemical biomarkers in sedimentary rocks tell scientists that brown algae were already photosynthesizing in shallow coastal waters long before the first mammals appeared.

Giant kelp, Macrocystis pyrifera, holds the title for the fastest-growing marine organism on Earth—it can shoot up more than half a meter a day under ideal conditions! 

These towering underwater forests provide shelter and food for thousands of marine creatures, from tiny snails to sea otters, who wrap themselves in the fronds to sleep without drifting away.

Back when I used to scuba drive a lot around Vancouver Island, they were one of my favourite places to explore as those underwater forests were teeming with life.

If you’re beachcombing in British Columbia, Alaska, or California, you might find bull kelp, Nereocystis luetkeana, recognizable by its long, whip-like stipe and single round float. It’s edible and surprisingly tasty. The blades can be dried and used like seaweed chips, while the bulb can be sliced thin and pickled—an oceanic delicacy with a salty, citrusy crunch. 

Other edible seaweeds you might encounter include sugar kelp, Saccharina latissima, which has a slightly sweet flavor, and ribbon kelp, Alaria marginata, often used in soups and salads.

On the foreshore near where I live on Vancouver Island, we have loads of sea lettuce. Sea lettuce, Ulva spp., is one of the ocean’s most vibrant and inviting greens—a delicate, translucent seaweed that looks like bright green tissue paper fluttering in the tide. 

Sea Otter in a Kelp Bed

When you find it washed ashore or swaying just below the surface, it shines an almost neon hue, catching the sunlight in shimmering waves of jade. 

Its thin, ruffled fronds are only a few cells thick, soft to the touch, and often cling to rocks, shells, or docks in intertidal zones where saltwater and freshwater mingle.

Unlike the giant brown kelps that form towering underwater forests, sea lettuce is part of the green algae group (Chlorophyta), sharing pigments more closely related to land plants. 

It grows worldwide in temperate and tropical waters and thrives wherever nutrient-rich water flows—estuaries, tide pools, and shallow bays. When the tide goes out, you might see it draped over rocks like sheets of emerald silk, drying slightly in the sun and releasing a faint, oceanic scent.

Sea lettuce is entirely edible and a favourite among foragers and coastal chefs. Fresh from the sea, it has a mild, slightly salty flavour with a hint of sweetness—similar to spinach or nori. It can be eaten raw in salads, lightly fried until crisp, or dried into flakes and used as a natural salt substitute. 

In many coastal cultures, from Ireland to Japan, Ulva has long been part of traditional cuisine. It’s also rich in vitamins A, C, and B12, along with iron and calcium—proof that sea greens can be as nutritious as they are beautiful. When my little sister was living in County Cork, she shared pictures of folk bathing in tubs of icy sea water and seaweed as a briny health spa treatment.

From a scientific perspective, sea lettuce plays an important ecological role. It provides shelter for small marine creatures like snails, shrimp, and juvenile fish, and it helps absorb excess nutrients from the water, which can help reduce harmful algal blooms. 

However, when too many nutrients enter the ocean—often from agricultural runoff—sea lettuce can grow explosively, creating dense “green tides” that blanket shorelines.

Its lineage stretches deep into the fossil record as well. While soft-bodied algae like Ulva rarely fossilize, green algal relatives appear in rocks over 1.6 billion years old, making them some of Earth’s earliest photosynthesizers.

Beyond their culinary and ecological roles, kelp forests act as powerful carbon sinks, pulling CO₂ from the atmosphere and storing it in the deep ocean. They also buffer coastlines from storms and provide nurseries for fish populations that support global fisheries.

As you stroll the shoreline and your toes brush against that slippery tangle of golden-brown ribbons, remember—you’re touching the living descendant of an ancient lineage that’s been swaying in Earth’s oceans since the age of dinosaurs—beautiful, ancient and tasty!

EOCENE PLANT MATERIAL

GULLS ON THE FORESHORE: T'SIK'WI

A gull cries in protest at not getting his share of a meal

Gulls, or colloquially seagulls, are seabirds of the family Laridae in the suborder Lari. 

The Laridae are known from not-yet-published fossil evidence from the Early Oligocene — 30–33 million years ago. 

Three gull-like species were described by Alphonse Milne-Edwards from the early Miocene of Saint-Gérand-le-Puy, France. 

Another fossil gull from the Middle to Late Miocene of Cherry County, Nebraska, USA, has been placed in the prehistoric genus Gaviota. 

These fossil gulls, along with undescribed Early Oligocene fossils are all tentatively assigned to the modern genus Larus. Among those of them that have been confirmed as gulls, Milne-Edwards' "Larus" elegans and "L." totanoides from the Late Oligocene/Early Miocene of southeast France have since been separated in Laricola.

Gulls are most closely related to the terns in the family Sternidae and only distantly related to auks, skimmers and distantly to waders. 

A historical name for gulls is mews, which is cognate with the German möwe, Danish måge, Swedish mås, Dutch meeuw, Norwegian måke/måse and French mouette. We still see mews blended into the lexicon of some regional dialects.

In the Kwak̓wala language of the Kwakwaka'wakw, speakers of Kwak'wala, of the Pacific Northwest and my family, gulls are known as t̕sik̕wi. Most folk refer to gulls from any number of species as seagulls. This name is a local custom and does not exist in the scientific literature for their official naming. Even so, it is highly probable that it was the name you learned for them growing up.

If you have been to a coastal area nearly everywhere on the planet, you have likely encountered gulls. They are the elegantly plumed but rather noisy bunch on any beach. You will recognize them both by their size and colouring. 

Gulls are typically medium to large birds, usually grey or white, often with black markings on the head or wings. They typically have harsh shrill cries and long, yellow, curved bills. Their webbed feet are perfect for navigating the uneven landscape of the foreshore when they take most of their meals. 

Most gulls are ground-nesting carnivores that take live food or scavenge opportunistically, particularly the Larus species. Live food often includes crab, clams (which they pick up, fly high and drop to crack open), fish and small birds. Gulls have unhinging jaws which allow them to consume large prey which they do with gusto. 

Their preference is to generally live along the bountiful coastal regions where they can find food with relative ease. Some prefer to live more inland and all rarely venture far out to sea, except for the kittiwakes. 

The larger species take up to four years to attain full adult plumage, but two years is typical for small gulls. Large white-headed gulls are typically long-lived birds, with a maximum age of 49 years recorded for the herring gull.

Gulls nest in large, densely packed, noisy colonies. They lay two or three speckled eggs in nests composed of vegetation. The young are precocial, born with dark mottled down and mobile upon hatching. Gulls are resourceful, inquisitive, and intelligent, the larger species in particular, demonstrating complex methods of communication and a highly developed social structure. Many gull colonies display mobbing behaviour, attacking and harassing predators and other intruders. 

Certain species have exhibited tool-use behaviour, such as the herring gull, using pieces of bread as bait with which to catch goldfish. Many species of gulls have learned to coexist successfully with humans and have thrived in human habitats. Others rely on kleptoparasitism to get their food. Gulls have been observed preying on live whales, landing on the whale as it surfaces to peck out pieces of flesh. They are keen, clever and always hungry.

ON THE GLOVE

GROUSE GRIND

HIKING THE CHIEF

CRETACEOUS CAPILANO RIVER

If you are looking for a wee fossil day trip, then a stroll down to the Capilano River is just the thing.

From downtown Vancouver, drive through Stanley Park heading north over the Lion’s Gate Bridge. Take the North Vancouver exit toward the ferries. Turn right onto Taylor Way and then right again at Clyde Avenue. Look for the Park Royal Hotel. Park anywhere along Clyde Avenue.

From Clyde Avenue walk down the path to your left towards the Capilano River. Watch the water level and tread cautiously as it can be slippery if there has been any recent rain. Look for beds of sandstone about 200 meters north of the private bridge and just south of the Highway bridge. The fossil beds are just below the Whytecliff Apartment high rises.

You will see some exposed shale in the area. It does not contain fossil material. The fossils occur only in the sandstone. Interesting, but again, not fossiliferous are the many granitic boulders and large boulders of limestone which may have been brought down by glaciers from as far away as Texada Island. Cretaceous plant material (and modern material) found here include Poplar (cottonwood) Populus sp. Bigleaf Maple, Acer machphyllum, Alder, Alnus rubra, Buttercup Ranvuculus sp., Epilobrium, Red cedar, Blackberry and Sword fern.

LINGULA ANATINA: PRIMATIVE BRACHIOPOD

Lingula anatina — a primitive brachiopod 

One of the most primitive brachiopods is this caramel and cream fellow, Lingula anatina. 

Brachiopods are marine invertebrates with a stalk and two shells connected along a hinge. They are often confused with bivalves such as clams. 

Bivalves have shells on the sides of their bodies. Brachiopods have shells on the top and bottom. As a result, the plane of symmetry in a bivalve runs along the hinge while it runs perpendicular to the hinge in brachiopods. 

Lingula forms are regarded as the most primitive brachiopods and represent the first certain appearance of brachiopods in the fossil records dating back 530 million years. 

Their shells do not have any locking mechanisms. Instead, they rely on complex musculature to move their shells. They are the first known examples of animal biomineralisation — a process whereby living organisms stiffen or harden tissues with minerals. Their shells are composed of calcium phosphate and collagen fibres, characters shared only by evolutionarily distant vertebrates.

Lingulid brachiopods had changed so little in appearance since the Silurian, 443-419 million years ago, they are referred to as living fossils — a term bestowed upon them by Charles Darwin himself.

Photo: Wilson44691 - Own work, Public Domain, https://commons.wikimedia.org/w/index.php?curid=8624418

PLANNING YOUR NEXT STAYCATION: HORNBY ISLAND

Hornby is so many things to so many people. I have avid pottery afficianato friends who go to look through the talented work of local potters. Others swear by the pie. It is off the beaten track and pure heaven.

TAKING IN THE VIEW

One of the most satisfying moments is taking in a sunset after a long days hike. Pure visual poetry. Peaceful, meditative and well-earned. It is a time for reflection on the day, your world, fresh blisters - the gamut!

Have you ever wondered about the colors you see in these moments? What sunlight actually is? Yes, it's light from the Sun but so much more than that. Sunlight is both light and energy. Once it reaches Earth, we call this energy, "insolation," a fancy term for solar radiation. The amount of energy the Sun gives off changes over time in a never ending cycle. Solar flares (hotter) and sunspots (cooler) on the Sun's surface impact the amount of radiation headed to Earth. These periods of extra heat or extra cold (well, colder by Sun standards...) can last for weeks, sometimes months.

The beams that reach us and warm our skin are electromagnetic waves that bring with them heat and radiation, by-products of the nuclear fusion happening as hydrogen nuclei shift form to helium. Our bodies convert the ultraviolet rays to Vitamin D. Plants use the rays for photosynthesis, a process of converting carbon dioxide to sugar and using it to power their growth (and clean our atmosphere!) That process looks something like this: carbon dioxide + water + light energy -->glucose + oxygen = 6 CO2(g) + 6 H2O + photons → C6H12O6(aq) + 6 O2(g) Photosynthetic organisms convert about 100–115 thousand million metric tonnes of carbon to biomass each year, about six times more power than used my us hoomins.

We've yet to truly get a handle on the duality between light as waves and light as photons. Light fills not just our wee bit of the Universe but the cosmos as well, bathing it in the form of cosmic background radiation that is the signature of the Big Bang.

Once those electromagnetic waves leave the Sun headed for Earth, they reach us in a surprising eight minutes. We experience them as light mixed with the prism of beautiful colors. But what we see is actually a trick of the light. As rays of white sunlight travel through the atmosphere they collide with airborne particles and water droplets causing the rays to scatter. We see mostly the yellow, orange and red hues (the longer wavelengths) as the blues and greens (the shorter wavelengths) scatter more easily and get bounced out of the game rather early.

CASTLE PEAK FOSSIL FIELD TRIP

HARRISON LAKE FOSSIL FIELD TRIP

CADOCERAS TONNIENSE

RAIN OR SHINE

EOCENE FOSSIL FIELD TRIP

There was a large downpour of rain that hit Washington State. It resulted in a huge slide at Sumas Mountain that revealed several large exposures of fossil plants, shorebird trackways and the trackways of the large flightless bird Diatryma.

Many of these finds can now be seen at museums in Washington State. While less abundant, evidence of the animals that called this ancient swamp home are also found here. Rare bird, reptile, and mammal tracks have been immortalized in the soft muds along ancient riverways.

HIGH ELEVATION FOSSIL FIELD TRIP

FERGUSONITES HENDERSONAE

A few years ago, I had the very great honour of having a new species of ammonite named after me by paleontologist, Louse Longridge.

Meet Fergusonites hendersonae, a Late Hettangian ammonite from the Taseko Lake area of British Columbia, high up in the Canadian Rockies.

He looks a wee bit like the Cadoceras comma we find in the Mysterious Lake Formation at Harrison Lake but a wee bit thinner and smaller.

KAYAK SAILING THE WEST COAST