Tag: Fossil

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Priceless and Primordial

Cataloguing the Brasier Collection

In 2021, the Museum was grateful to host PhD students Sarah Skeels and Euan Furness on research internships. Together, Sarah and Euan made a significant contribution to the cataloguing of the Brasier Collection — a remarkable assembly of fossils and rocks donated to the Museum by the late Professor Martin Brasier. Here, Sarah and Euan recount their experiences inventorying this priceless collection of early lifeforms.

Sarah Skeels is a DPhil Student in the Department of Zoology, University of Oxford

My short internship at the Oxford University Museum of Natural History came at a transitional point in my research career, starting a few days after submitting my PhD thesis. By training, I am a Zoologist, and my PhD thesis is on the electrosensing abilities of weakly electric fish. However, I have had an interest in Palaeontology for a long time, having studied Geology as part of my undergraduate degree. As such, the internship provided me with a unique opportunity to reflect on a subject I had studied many years before, whilst also developing new academic research skills.

The goal of my internship was to improve the inventory of the microfossils held in The Brasier Collection and to photograph some of these specimens, all in the hopes of increasing the utility of the collection to students, researchers, and hobbyists alike.

Obtusoconus, a fossilised mollusc from Iran, is less than 0.5mm in width. The specimen has been gold-coated in preparation for scanning electron microscopy. Brasier Collection, Oxford University Museum of Natural History.
A collection of Siphogonuchites, small shelly fossil organisms, found in Mongolia. Brasier Collection, Oxford University Museum of Natural History.

The Brasier Collection is rich in microfossils — small fossils that can only properly be inspected with either a light or electron microscope. Those stored in the Collection represent the fragmentary remains of a diverse array of animal groups that lived in the Cambrian, an important period in the Earth’s history when animal life diversified hugely, giving rise to many of the modern phyla that we know and love. The microfossils I examined came from a number of localities across the globe, including Maidiping in China and Valiabad in Iran. The specimens are exquisite in detail, which makes it difficult to believe that they are hundreds of millions of years old.

These fossils are of huge importance, helping us to understand the emergence of early animal life, and its evolution into all of the wonderful forms that exist today. The fossils are also useful because they can serve as markers of the age of different rock forms. By helping to improve the way these specimens are catalogued, I like to think that I am contributing to the preservation of Professor Brasier’s legacy. The whole experience was incredibly rewarding, and I can’t wait to see what new discoveries are made by those who study this unique set of fossils.

Euan Furness is a PhD student at Imperial College London

Oxford University Museum of Natural History has a range of objects on display to the public, but a lot of the curatorial work of the Museum goes on behind the scenes, conserving and managing objects that never come into public view. Collection specimens often don’t look like much, but they can be the most valuable objects to researchers within and outside the Museum. While there are a few visually striking pieces in the Brasier Collection, the humble appearance of most of the Brasier specimens belies their importance.

Left: A photo of Professor Brasier (bottom right) and friends, found in the Collection. Middle: Euan cataloguing in the Hooke basement. Right: An unusually well-preserved archaeocyathid (extinct sponge) from the Cambrian of Australia. Photo by Euan Furness.

The Brasier Collection came to the Museum in bits and pieces from the Oxford University Department of Earth Sciences, with the last of the specimens arriving in September 2021. The Museum therefore needed to determine exactly what they had received before they could decide how to make the best use of it. This meant searching through boxes and drawers behind the scenes and pulling together as much information as possible about the new objects: dates and locations of collection, identity, geological context, and the like. Only then could the more interesting specimens be integrated with the existing collections in the drawers of the Museum’s Palaeozoic Room.

Owing to Professor Brasier’s research interests, the addition of the Brasier Collection to the Museum’s catalogue more than doubled the volume of Precambrian material in its drawers. With that in mind, it was finally time for the Precambrian to be given a set of cabinets to call its own. This seems only fair, given that the Precambrian was not only a fascinating period in the Earth’s history but also the longest!

Having sorted through the new Brasier Collection at length, I think it’s not unreasonable to hope that the unique array of objects it adds to the Museum’s collections will facilitate a great deal of research in the future. For that, we must thank Martin for his generosity.

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Reconstructing the Cretaceous with Bones and Amber

A double window into the past

Post by Dr Ricardo Pérez-de la Fuente, Deputy Head of Research

Nature is wonderfully imperfect, and the data that we can gather from it is even further from perfection. Fossil localities, even those providing exceptionally well-preserved fossils, are inaccurate records of the past. Fossils can form from a variety of matter including organisms, their remains, or even traces of their activity. Yet not all of the material that can get fossilised at a particular site actually will. Among other factors, biases in the fossil record result from the nature of the materials responsible for fossilisation – usually sediments which are in the process of turning into rocks. In most cases, fossil localities offer us only a single ‘window of preservation’ – a skewed geological record of the ancient ecosystem that once existed there.

In 2012, a rich vertebrate bone bed was documented at the Ariño site in Teruel, Spain. Since then, researchers have unearthed more than 10,000 individual fossil bones, from which they have discovered new species of dinosaurs, crocodiles, and turtles. Plant fossils were also found, including pollen grains and amber, which is fossilised resin. Although amber was known to occur in this locality, this sort of material had remained unstudied… until recently.

Over the summer of 2019, I joined my colleagues to carry out amber excavations in the Ariño site – an open-pit coal mine that has an almost lunar appearance due to the dark carbonate-rich mudstone rocks and the total lack of vegetation. The scorching heat during a very hot summer was a bit maddening, but I did try to enjoy my yearly dose of sun before returning to the UK!

Manual extraction of amber from Ariño during the 2019 summer campaign
A selection of fossil insects found in Ariño amber: a true fly belonging to an extinct family (left), a platygastroid parasitoid wasp (top right), and a thrips (bottom right). Modified from Álvarez-Parra et al. 2021.
(Left) Manual extraction of amber from Ariño during the 2019 summer campaign.
(Right) A selection of fossil insects found in Ariño amber: a true fly belonging to an extinct family (left); a platygastroid parasitoid wasp (top right); and a thrips (bottom right). Modified from Álvarez-Parra et al. 2021.


Resin pieces can be transported significant distances by runoff water before depositing on their final burial location, where they slowly transform into amber. However, we found amber pieces that had not moved from their original place of production. These large, round-shaped pieces preserved delicate surface patterns that would have been polished away even by the slightest transport. The resin that produced these amber pieces was formed by the roots of the resin-producing trees, and resembles sub-fossil resin my colleagues found in modern forests from New Zealand.

Large amber piece produced by roots (left) and assemblage of smaller amber pieces (right) from Ariño (Teurel, Spain).
Large amber piece produced by roots (left) and assemblage of smaller amber pieces (right) from Ariño (Teurel, Spain).

The small amber pieces from Ariño contain an unusual abundance of fossils. These pieces come from resin produced by the branches and trunk of the resin-producing trees. From the almost one kilogram of amber we excavated, we identified a total of 166 fossils. These include diverse insects such as lacewings, beetles, or wasps, and arachnids such as spiders and mites. Even a mammal hair strand was found!1

We now know that the Ariño site provides two complementary windows of preservation — a bone bed preserving a rich variety of vertebrate animals, and amber with abundant inclusions. Aside from Ariño, only three localities that preserve both dinosaur bone beds and fossiliferous amber have been reported in Western France, Western Canada, and North Central United States. However, in these cases, either the bone bed or the amber have offered a much more modest abundance and diversity of fossils. Some of the fossils from these localities also show signs of significant transport, which means that the organisms could have inhabited different, distant areas even though they fossilised together. This makes Ariño unique because it offers two valuable ‘windows of preservation’ from the same ecosystem.

Thanks to all this evidence and other data, we have been able to reconstruct an ancient terrestrial ecosystem – a 110-million-year-old coastal swamp – with unprecedented detail and accuracy.2 The inherent incompleteness of the fossil record will always remain a headache for palaeontologists… but localities like Ariño make the data that we can recover from the past a bit more complete.

Reconstruction of the coastal swamp forest of Ariño, in the Iberian Peninsula, from 110 million years ago. Author: José Antonio Peñas. Source: Álvarez-Parra et al. 2021.
Reconstruction of the coastal swamp forest of Ariño, in the Iberian Peninsula, from 110 million years ago. Author: José Antonio Peñas. Source: Álvarez-Parra et al. 2021.

If you want to learn more about amber excavations, check out this post on Excavating Amber.

1Álvarez-Parra, Sergio, Ricardo Pérez-de la Fuente, Enrique Peñalver, Eduardo Barrón, Luis Alcalá, Jordi Pérez-Cano, Carles Martín-Closas et al. “Dinosaur bonebed amber from an original swamp forest soil.” Elife 10 (2021): e72477.

2Álvarez-Parra, Sergio, Xavier Delclòs, Mónica M. Solórzano-Kraemer, Luis Alcalá, and Enrique Peñalver. “Cretaceous amniote integuments recorded through a taphonomic process unique to resins.” Scientific reports 10, no. 1 (2020): 1-12.

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The Geology of Oxford Gravestones

By Duncan Murdock, Earth Collections manager

A cemetery may seem like an unusual location for a geology fieldtrip, but for rock hounds from beginner to professor there’s a treasure trove of different rock types in gravestones. Whether it’s shells of oysters from the time of the dinosaurs, or beautiful feldspar crystals formed deep within the Earth’s crust, rocks are uniquely placed to tell the story of the history of our planet.

This incredible resource is elegantly celebrated in a new temporary exhibition in the Weston Library in Oxford. Compiled by two of the Museum’s Honorary Associates, Nina Morgan and Philip Powell, The Geology of Oxford Gravestones brings together the geological and human history of Oxford’s cemeteries.

  • Headstone in grass cemetery
    The gravestone for Henry John Stephen Smith, second keeper of the Museum, in St Sepulchre’s cemetery. It is a wonderful example of Shap Granite from quarries in Cumbria. Image: Mike Tomlinson.
  • Headstone in grass cemetery
    This imposing monument in Holywell cemetery, made of granite from Cornwall, marks the graves of the Acland family, including that of Henry Acland, one of the founders of Oxford University Museum of Natural History. Image: Mike Tomlinson.

The exhibition is illustrated with artefacts including undertakers’ trade cards and ‘rules of burial’, rock samples from the Museum’s collections, and photographs of headstones from Museum luminaries such as Henry John Stephen Smith, our second Keeper, and Henry Acland, one of our founders.

The Geology of Oxford Gravestones exhibition poster

Although compact, the exhibition is full of fascinating snippets for fans of geology and social history alike, even bringing the science right up to date with a study using lichen on gravestones to understand our changing environment. The text and objects on display are enhanced by rolling digital displays that give more insight and colour to the story.

As the exhibition says, “visit a cemetery with a hand lens and you’ll be amazed at what you can see, you’ll never look at cemeteries in the same way again”. Just make sure you visit the display in the Weston Library first!

The Geology of Oxford Gravestones, is in the Blackwell Hall foyer of the Weston Library in Broad Street, Oxford and runs from 17 July to 12 September 2021. You can also find out more about Gravestone Geology here and in our previous post Celebrate science in a cemetery.

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The Evolution of Plants

To mark Plant Appreciation Day today, Lauren Baker and Chris Thorogood of the University of Oxford Botanic Garden and Arboretum take us on a quick tour of the evolution of plants: from primitive water-dwelling algae to the colonisation of land, and the eventual success of angiosperms – the flowering plants.

The Earth formed around 4.6 billion years ago, and around 2.7 billion years ago the very first plants evolved. These were the algae, a diverse group that live mainly in water. The ancestor of all modern algae – and the first organisms to photosynthesise – were cyanobacteria. Green algae evolved from these cyanobacteria and are the ancestors to all modern plants.

We owe the air we breathe to plants. With the production of oxygen through photosynthesis came a drastic climatic shift around 2.4-2.0 billion years ago. Known as the Great Oxygenation Event, it dramatically increased oxygen and decreased carbon dioxide in the atmosphere.

  • Red-coloured, irregular shaped fossil imprint on pale stone
    Fossil of Margaretia dorus, a 500 million year old algae from Utah, USA
  • Algae growing in the Outdoor Water Lily Pond at Oxford Botanic Garden

Non-flowering plants

Jump ahead 1.5 billion years and the evolution of plants really takes off. To leave the water, plants needed to develop protection from drying out. The group that colonised the land is called the bryophytes, and includes the liverworts, hornworts and mosses.

Bryophytes are simple plants that lack true roots or ‘plumbing’ vascular tissue such as xylem or phloem. Bryophytes may have evolved from green algae in shallow, fresh water and developed the ability to survive on land when these pools dried out: 470 million years on, you can still see many bryophytes growing in damp habitats today.

A living bryophyte: Marchantia species growing in the Carnivorous House at Oxford Botanic Garden

The first vascular plants appear around 430 million years ago. One of the earliest examples was Cooksonia, consisting of a simple branching stalk without leaves.

  • Fossilised Cooksonia, one of the earliest vascular plants. This 420-million-year-old fossil is from Lower Wallop in Shropshire. OUMNH C.31324.
  • Fossilised Cooksonia, one of the earliest vascular plants. This 420-million-year-old fossil is from Lower Wallop in Shropshire. OUMNH C.31324.

Lycophytes, which evolved around 350 million years ago, also have vascular systems that enable water and nutrients to be moved around the plant. This drove the evolution of more complex, multicellular plants.

The ability to pump water allowed lycophytes to grow to heights of 45 m and they formed vast forests. Their remains also make up the coal, oil, and natural gas we use for energy today. More than 1,200 species of lycophytes exist now, grouped into three orders: the club mosses, quillworts and spike mosses.

  • Repeated pattern fossil imprint on dark grey stone
    Fossilised remains of Lepidodendron, an extinct genus of primitive lycophytes
  • Living lycophytes: Selaginella, growing in the Cloud Forest House at Oxford Botanic Garden

A ‘living fossil’ that can be seen growing at the Botanic Garden is Equisetum, commonly called the horsetail. Horsetails evolved around 350 million and although the species alive today are herbaceous, extinct horsetails such as Calamites once formed large trees. The fossilised remains of Calamites in the collections of the Museum show the vascular tissues that would have carried water and nutrients up the vast trunk of the tree.

  • Striated fossil imprint on dark grey stone
    Extinct horsetails such as this Calamites once formed large trees. This 300 million year old fossil is from Rhondda Valley, Wales 
  • Horsetail today at Oxford Botanic Garden

​Cycads also evolved around the same time as the lycophytes and horsetails. They could easily be confused with palms, but unlike palms they are not flowering plants. Cycads belong to a group of plants called the gymnosperms, a name that literally means ‘naked seed’, and refers to the plants’ reproduction with seeds that are not encased in an ovary. Cycads can survive for over 1,000 years and are very slow growing. Today, the majority of the 200 surviving species are threatened with extinction.

  • Cycas revoluta, a cycad, growing in the Conservatory at Oxford Botanic Garden
  • Other living gymnosperms that evolved alongside cycads include the conifers, of which there are many, and ginkgos, of which today there is just one surviving species: Ginkgo biloba, pictured growing at Oxford Botanic Garden

​Another ancient and unusual group of gymnosperms that evolved alongside cycads and lycophytes are Gnetophytes, which include plants such as Ephedra, Welwitschia, and Gnetum. There are about 40 living species of Gnetum, and they are tropical evergreen trees, shrubs and lianas. Before DNA sequencing technology, they were believed to be the closest living relatives of flowering plants due to the sugary sap they produce to attract pollinating insects, like the nectar produced by flowers.

Fossils of Ephedra date back as long as 120 million years ago. They are pollinated by both wind and insects, and are found across all continents except for Australia. With small, scale-like leaves they are highly adapted to arid environments, growing in sandy soils with direct sun exposure.

But perhaps the most familiar gymnosperms are the conifers. Conifers include the world’s oldest tree, the bristlecone pine, and the world’s largest tree, the giant Sequoia. There are over 615 species of conifers, most belonging to the pine family, Pinaceae.

  • Branching pattern fossil imprint on brown stone
    Brachyphyllum expansum, an extinct conifer which belonged to the family Araucariaceae – famous for including the monkey puzzle tree
  • A monkey puzzle tree, Araucaria araucana, at Oxford Botanic Garden

Flowering plants​

The evolution of flowering plants – the angiosperms – 125 million years ago, was the start of a global botanical competition with gymnosperms, and it changed the appearance of our planet forever. The fossil record shows the earliest flowering plants bloomed alongside the dinosaurs, and probably looked something like a magnolia.

Magnolia stellata blooming at Oxford Botanic Garden

Unlike the gymnosperms, the angiosperms reproduce with flowers and their seeds are contained within protective ovaries. Despite their relatively late emergence, the diversity of flowering plant species was accelerated by their evolution alongside insect pollinators. Today, of the roughly 350,000 known plant species, 325,000 are flowering plants.

  • Fossil leaf imprint on pale stone
    Whilst more famously known for their foliage, acers are also angiosperms. This fossil of Acer tricuspidatum is 30 million years old, from Oeningen, Switzerland 
  • One of the many Acer species showcasing its autumn colour at Harcourt Arboretum
Bright pink and purple flower
Large, open yellow flower
Red and yellow flower
Orange sunflower head
Red, orange, yellow flower
Purple plants with bees

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Rare Jurassic mammal fossil from Scotland is new species

By Elsa Panciroli, Research Fellow

This week my colleagues and I announced the discovery of a new species of mammal from the time of dinosaurs. It is one of two rare skeletons we’re studying from the Isle of Skye in Scotland. These mouse-like animals lived in the Middle Jurassic (166 million years ago), and tell us about the evolution of mammals in the time of dinosaurs.

The two fossils belong to Borealestes serendipitous and Borealestes cuillinensis. B. serendipitous was the first Jurassic mammal ever found in Scotland, known originally from pieces of fossil jaw found on Skye in 1971. In our new paper, we describe the skull of a partial skeleton of this species, found in 1972 by the original discoverer of the site, Dr Michael Waldman and his colleague Prof Robert Savage. But this exceptional fossil lay unstudied for over 40 years. Only now is it giving up its secrets thanks to powerful synchrotron X-ray scans, which reveal the anatomy in incredible detail.

The other fossil skeleton was found in 2018 by my colleague Prof Richard Butler. After taking it back to the lab and CT-scanning it, we realised it was a new species. We named it Borealestes cuillinensis in honour of the Cuillin mountain range on Skye (Gaelic: An Cuiltheann), a stunningly jagged set of peaks that overlooks where the discovery was made.

The fossil jaw of new species, Borealestes cuillinensis, moments after its discovery. By Elsa Panciroli

Most ancient mammals are only known from a few teeth and jaws, so these skeletons are exceptionally rare. They are currently the most complete Jurassic mammals described from the UK.

The Middle Jurassic is an important time in animal evolution, because it marks an increase in the diversity of lots of different groups. Just afterwards, in the Late Jurassic, there are many new species of mammals, amphibians, small reptiles and dinosaurs, which flourish into the Cretaceous period. All of this diversity began in the Middle Jurassic, but fossils from that time are rare, making it difficult to unpick the causes of these changes. This means that any material from that time period is extremely important to our understanding of the course of evolution, and the drivers of animal diversity.

Fieldwork team on the Isle of Skye: (L to R) Roger Benson (University of Oxford), Richard Butler (University of Birmingham), Elsa Panciroli (OUMNH and National Museums Scotland), Stig Walsh (National Museums Scotland).

Our team have been carrying out fieldwork and research on Skye for the last decade. It includes researchers from National Museums Scotland and the universities of Oxford and Birmingham. We are working on many more exciting fossils from the island, so keep an eye out for the next discovery!

Read the paper ‘New species of mammaliaform and the cranium of Borealestes (Mammaliformes: Docodonta) from the Middle Jurassic of the British Isles’ published today in the Zoological Journal of the Linnean Society.

Top image: Digital reconstruction of two Jurassic mammal skulls. (c) Matt Humpage

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Celebrate science in a cemetery

By Nina Morgan, Gravestone Geology

Cemeteries not only provide a peaceful place to commemorate the dead, and observe and enjoy nature; they are also wonderful repositories for the study of local history and art. But that’s not all. Cemeteries also offer an easy introduction to science that anyone can enjoy.

A visit to a cemetery presents a wonderful way to learn about geology and the other sciences, such as chemistry, physics and engineering, that underpin it. For geologists – whether amateur, student or professional – almost any urban cemetery provides a valuable opportunity to carry out scientific fieldwork at leisure, right on the doorstep, and at no cost.

Headington Municipal Cemetery, Oxford

Geology on show

Because gravestones are made from a wide variety of rock types formed in a range of geological settings, cemeteries can be geological treasure-troves. Many headstones are made of polished stone, so reveal details – such as minerals and crystal features – that are not easy to see elsewhere. Some demonstrate the textures and mineral composition of igneous rocks – rocks formed when molten magma cooled and solidified. Others are happy hunting grounds for lovers of fossils. Some gravestones reveal sedimentary structures that show how the rock was originally deposited. Others provide clues to earth movements and environments that occurred hundreds of millions of years ago.

For those interested in engineering, examination of gravestones can also provide useful information about topics ranging from weathering of stone to atmospheric chemistry, effects of pollution, stability and settling in soils and land drainage. 

St Andrews Church in Headington, Oxford

Cemeteries in Oxford include ancient churchyards, such as St Andrews Headington, as well as Victorian cemeteries like Holywell (pictured top) and St Sepulchres, and more modern burial grounds, such as Headington Municipal cemetery. Together they exhibit the main features and stone types that can be seen in cemeteries all around Britain.

St Sepulchres Cemetery, Oxford

In the short video below, filmed in the churchyard of St Mary and John in Oxford’s Cowley Road, Philip Powell and I introduce the basics and show you how to get started in exploring these geological gems. If you want to learn more, visit www.gravestonegeology.uk. But be warned – gravestone geology can be addictive. Once you’ve got your eye in, you’ll never look at cemeteries in the same way again!

All images and video by Mike Tomlinson.