Article

Limestone, a fizzy rock – introduction

Limestone is an unusual rock in that it fizzes when dilute acid is placed on its surface. It is the presence of calcium carbonate that is responsible for this. The calcium carbonate content of limestone rocks has been used from the earliest civilisations, dating back to 14,000 BCE, to its extensive use in modern times.

Dilute acid placed on a sample of limestone rock in a jar

Limestone – the fizzy rock

When dilute acid is placed on a sample of limestone rock, it fizzes. The calcium carbonate present in the limestone is reacting with the acid to produce carbon dioxide gas.

Rights: The University of Waikato Te Whare Wānanga o Waikato

Limestone is a rock that dominates the landscape in many areas of New Zealand and is literally ‘fizzing’ with uses and applications, so it deserves closer inspection that will reveal some interesting chemistry, geology and biology.

Limestone origins

Limestone is a very common sedimentary rock composed mostly of the mineral calcite. Most limestones have a marine origin, being formed by the accumulation of shells and shell fragments of once-living marine organisms such as molluscs, bryozoans and corals. Other limestones, such as cold-seep carbonates, have been derived from non-biogenic mineral formation as a result of direct crystallisation of calcium carbonate from water. Find out more in the articles Limestone origins and New Zealand limestone origins.

Biomineralisation

If most limestones have a biogenic origin, it may be of value to discover how marine organisms like bryozoans and molluscs extract calcium carbonate from seawater and lay it down in crystalline form to form a hard protective outer casing or shell. By understanding the biological and chemical principles that are at work, these natural processes may be able to be reproduced in the lab to develop a new generation of materials for everyday use. Find out more in the article Calcium carbonate biomineralisation.

Biomineralisation explained

Professor Kate McGrath, of the MacDiarmid Institute, explains the process by which organisms that have hard structures such as bone and shell deposit mineral-rich hard tissues. The process is called biomineralisation. In the case of shellfish like pāua, it involves the laying down of a combination of the inorganic mineral calcium carbonate with biological components such as proteins and carbohydrates.

Rights: University of Waikato. All Rights Reserved.

Carbonate chemistry

Limestone contains more than 50% calcium carbonate in the form of the minerals calcite and aragonite. High-grade limestone can be close to 100% calcium carbonate. Calcium carbonate has a wide range of uses, and a study of its physical and chemical properties will help to explain why it has so many applications. Find out more in the article Carbonate chemistry.

Lime – a ‘top 10’ chemical

The term ‘lime’ is used for several calcium compounds. Pure lime is calcium oxide, which is produced industrially by the thermal decomposition of limestone. As a ‘top 10’ chemical in terms of worldwide production, lime plays a key role in a multitude of industrial, manufacturing and agricultural processes. Find out more in the article Lime – a time-tested chemical.

Limestone uses

Limestone is quarried for aggregate and building stone for use in road and building construction, as well as being used for making agricultural fertiliser, cement, steel and glass. High-purity limestone is used as a mineral filler in paper, paint, plastics, rubber and carpet backings as well as in water treatment and as a dusting agent in coal mining to prevent fires. Find out more in the article Limestone uses.

Limestone landscapes

Limestone is a sedimentary rock that is partially soluble, especially in rainwater, which is naturally acidic, and therefore forms many erosional landforms. It dominates the landscape in many areas of New Zealand such as the Waitomo region of Waikato, Te Mata Peak in Hawke’s Bay, the Matiri Range in Nelson and Punakaiki in central West Coast. These landscapes have considerable tourism value. Find out more in the article Limestone landscapes.

Kayaker on the Mōkau River, Taranaki, New Zealand.

Mōkau River gorge

Limestone cliffs in the Mōkau River gorge. Weathering and erosion along with surface uplift have created this deep gorge in the Mōkau River, Taranaki.

Rights: Green Party of Aotearoa New Zealand

Meet the scientists

Professor Kathryn McGrath is director of the MacDiarmid Institute for Advanced Materials and Nanotechnology. One of her research interests focuses on calcium carbonate biomineralisation. The long-term goal of this work is to apply the mechanisms of biomineralisation to develop human bone replacement materials that can be used in the medical setting.

Professor Cam Nelson from the Earth Sciences Department at the University of Waikato is regarded as one of New Zealand’s limestone experts. His research work in this area has spanned a lifetime and has led to a clearer understanding of limestone formation in temperate marine environments.

Dr Steve Hood works closely with Professor Nelson, and one of his research interests focuses on cold-seep carbonates, both modern and ancient.

Often associated with cold-seep sites is a vibrant community of chemosynthetic organisms. Dr Ashley Rowden from NIWA specialises in the identification of these unique living forms.

Take up the challenge

The related student activities are a combination of worksheet-based, practical and art experiences.

Limestone to lime uses the interactive Calcination (the industrial processing of limestone into lime) to complete a matching activity. Toilet roll geological timescale uses a toilet roll to mark major New Zealand geological events. In Discovering limestone's secrets, students answer graded sets of questions based on the interactive Limestone secrets revealed.

Practical activities include Some properties of carbon dioxide, testing the Strength of sand and cement mixtures and measuring soil pH in Liming paddocks.

Art enthusiasts can prepare a tile of lime plaster, paint it in the fresco style and learn about Fresco painting chemistry.

Model stalactite and stalagmite formations.Then extend the model to see how speleothems act as climate proxies.

Question bank

The Limestone, a fizzy rock – question bank provides an initial list of questions about limestone’s geology, biology, chemistry and uses, places where their answers can be found. The questions support an inquiry approach.

Key terms

For explanations of key concepts, see Limestone, a fizzy rock – key terms.

Timeline

Explore the timeline to see some important dates in the history of limestone from Egyptian pyramid building to modern day industries.

Related content

The article Why caves matter explains how cave formations can inform us about the past.

Published: 1 October 2012,Updated: 1 October 2012