Chapter 3. Igneous Rocks

3.1 | A geologist at the Hawai’ian Volcano Observatory collects a sample of lava for later chemical analysis. The inset image is an example of a labelled sample bag, recording where, when, and how the sample was collected. Source: USGS (2020) Public Domain. View image.

Click here to read more about what’s happening in Figure 3.1.

Introduction

All rocks found on the Earth are classified into one of three groups: igneous, sedimentary, or metamorphic. This classification is based on the origin of each of the rock types. The focus of this chapter will be on igneous rocks, which are the only rocks that form from what was once a molten or liquid state. Therefore, igneous rocks are defined as those rock types that form by the cooling of magma or lava. Each igneous rock has a name that distinguishes it from other igneous rocks.

Igneous rocks differ from each other primarily due to:

  1. the original composition of the molten material from which the rock is derived, and
  2. the cooling process of the molten material that ended up forming the rock.

These two parameters are the basis for a classification system for igneous rocks that is based on composition and texture. The composition of an igneous rock refers to the minerals in the rock, and their chemical make-up. The texture of an igneous rock refers to visible features such as the sizes of mineral grains making up the rock, the presence of glass, the presence fragmented material, or vesicles (holes).

Learning Outcomes

After completing this chapter, you should be able to:

  • Classify igneous rock types based on colour, texture, and mafic colour index
  • Identify, when possible, the minerals present in an igneous rock
  • Determine the cooling history of an igneous rock

Key Terms

  • Amygdaloidal
  • Aphanitic
  • Extrusive
  • Felsic (Silicic)
  • Ferromagnesian
  • Glassy
  • Intermediate
  • Intrusive
  • Mafic
  • Non-ferromagnesian
  • Phaneritic
  • Phenocryst
  • Porphyritic
  • Ultramafic
  • Vesicular

What’s Happening In This Figure?

This following article is from Volcano Watch for 19 March, 2020.Volcano Watch is part of the weekly volcanic activity update by the USGS’s Hawai’ian Volcano Observatory.

HVO’s geological sample collections are an important resource

On December 30, 2015, an HVO geologist wore protective gear during collection of a fresh lava sample for chemical analysis from a pāhoehoe breakout along scattered Pu‘u ‘Ō‘ō lava flows. Inset image caption: Metadata is written on a bag that holds a sample taken from pāhoehoe that was collected on August 18, 2006. The front of the bag notes the date and time the sample was collected, sample-collector initials, a description of the sample, and the unique sample identifier; the coordinates of the sample collection location are written on the back of the sample bag. USGS photos.

In the past, HVO would occasionally post images of people collecting lava samples on our website. These photos usually featured a person (with little-exposed skin) holding a rock hammer, with a metal bucket nearby. The bucket contained water to “quench” the sample, solidifying the hot lava into a cold glass. Natural-fiber or heat-resistant gloves, and sometimes a face mask, protected the sample collector from heat radiating off the 1150 ºC (2100 ºF) lava. The hammer was used to scoop some of the molten material into the bucket, which would hiss and steam in reaction; more water would be added to cool down the sample so it could be placed in a cloth bag.

HVO carefully archives or curates these precious geological samples collected by current and past HVO geologists, collaborators, visiting scientists, and volunteers. Most of the HVO samples were collected from around the Island of Hawai‘i over the past several decades as part of HVO’s mission to monitor eruptive activity (sampling active lava flows) or to characterize previous volcanic activity (sampling prehistoric lava flows on or beneath the surface). For samples collected within Hawai‘i Volcanoes National Park, HVO works closely with National Park Service archivists to ensure appropriate record keeping and tracking.

When a sample is collected, it’s important to document the sample’s “metadata.” This includes the name of the sample collector, coordinates marking sample location, and the collection date. If the sample was taken from molten lava, it’s labeled as a “quenched” sample, and the time of sample collection is also noted.

As part of metadata, geologists generally describe the sample location (such as the Southwest Rift Zone of Kīlauea) and characterize the sample itself (a grey-colored, discontinuous, fine ash, for example). Usually, the sample is given a unique identifier (ID), often a combination of numbers and letters, which is written on the sample bag. This ID connects the sample to its metadata, which is entered into a searchable database.

Much preparation and forethought go into sample collection, with prior project planning, permitting, and gaining permission from landowners. For every geologist, it’s important to ask: “What question(s) will this sample help me to answer?” Samples are collected sometimes because their specific chemistry or physical characteristics can reveal important information that helps scientists to understand the past, or on-going, or potential future volcanic activity and hazards.

For example, a sample of ash from the Ka‘ū Desert indicates that ash was deposited in that location at some point in the past and could, therefore, be deposited there in the future. Particle size and chemical analyses of the ash can provide information about the eruption magnitude (size) and character (was the eruption driven by steam or magmatic gas?).

Such information improves understanding of the range of behaviors Hawaiian volcanoes exhibited in the past and could exhibit in the future. Likewise, rapid analyses of molten lava samples during the 2018 lower East Rift Zone eruption allowed HVO to detect changes in magma chemistry that foretold a change in eruptive behavior—the arrival of increasingly hot and fluid lava—and associated hazards.

Several sample collections are currently being curated at HVO. The youngest consists of lava and ejecta from Kīlauea’s 2018 lower East Rift Zone eruption and summit-collapse events. Other collections include lava samples from historical eruptions of Kīlauea (including products of Pu‘u ‘Ō‘ō and ejecta collected downwind of Halema‘uma‘u when there was an active lava lake); geological samples that aided in creating the Geologic map of the Island of Hawaii; and ash and other ejecta collected as part of research to understand older explosive events in Kīlauea’s history. The Pu‘u ‘Ō‘ō collection in particular is perhaps unique in the world for its completeness and longevity covering a single eruptive event and is thus extremely valuable.

Each sample collection and resulting analytical data informs HVO and the wider volcanological community a little more about the behavior and hazards of Hawai’ian volcanoes. These collections will continue to be an important resource for researchers, especially because some samples are from areas that are no longer accessible, having been covered by more recent lava flows or within the area of Kīlauea’s summit that collapsed in 2018.

Eventually, one of Hawai’i’s volcanoes will erupt again, and HVO will have another sample collection to curate and care for, and to help us understand Hawaiian volcanoes and their hazards a little more.

Attributions

Adapted from:

McBeth, J., Panchuk, K., Prokopiuk, T., Hauber, L., & Lacey, S. (2020). Introductory Physical Geology Laboratory Manual, 1st Canadian Ed., Chapter 3. Igneous Rocks by L. Hauber & J. McBeth. CC BY-SA 4.0

Deline, B., Harris. R. & Tefend, K. (2015) Laboratory Manual for Introductory Geology, 1st Edition, Chapter 8. Igneous Rocks by K. Tefend. Harris. CC BY-SA 4.0

License

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Laboratory Manual for Earth Science Copyright © 2020 by Karla Panchuk is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License, except where otherwise noted.

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