Sedimentary Rocks Classification PDF

Summary

This document provides a classification of sedimentary rocks, focusing on the characteristics of clastic sedimentary rocks. It details the classification based on grain size and composition, using examples like quartz arenite and arkose. It also discusses the concept of compositional and textural maturity of sediments, and how climate and tectonic setting influence these characteristics.

Full Transcript

Sedimentary Rocks
ES301
3rd level
Lectures 4 & 5

Edited and collected
by
Safiya M. Hassan
Beni Suef University
2024
 The Classification of Clastic Sedimentary Rocks

A very basic classification of
all sedimentary rocks is
based on the type of material
that is deposited and the
modes of deposition.
Classification based on grain size

A simple classification of terrigenous clastic rocks and sediment is based
on the predominant grain size of the material:

Grain Sediment Rock Name Adjectives
Size1 name
(mm)
>2 Gravel Rudite Cobble, pebble, well
sorted, etc.
0.0625-2 Sand Arenite Coarse, medium, well
sorted, etc.
< 0.0625 Mud Mudstone Silt or clay
or
Lutite
1For the purposes of this general classification we will assign the rock or sediment
name shown if more than 50% of the particles are in the range shown. More
detailed classification schemes will limit terms on the basis of different proportions
of sediment within a given grain size.
Classification of Sandstones

Most sandstone classifications are based on the composition of the rock.

Dott’s classificaton scheme is used in most courses at Brock.

It is based on the relative proportions of:

Martrix (fine-grained - 95% Quartz =
Quartz arenite

25% Feldspar = arkosic composition
Arkose
>25% Feldspar = mineralogically
immature

Feldspar Lithics
PETTIJOHN CLASSIFICATION

Based on percentage of
matrix

Matrix poor (15%) – wackes

Wackes or (greywackes)
Tend to be dark in colour
Are poorly sorted
Clastic sedimentary rocks
can be made up of
“multicycled” particles.

i.e., have passed through the
rock cycle several times.

Each time through the cycle
the sediment becomes more
and more mature.
Sediment texture and mineralogical composition all reflect the maturity
of a sediment.
Most changes are related to transport distance, nature of weathering at
the site of sediment formation and number of passes through the rock
cycle.
i) Textural Maturity

Changes in grain size and shape.

Increasing textural maturity

Increased sorting

Increased rounding

Increased sphericity
 The name of a sandstone tells you something of its maturity.
E.g., a Quartz arenite has less than 15% matrix and is better sorted than
a Quartz graywacke.

The quartz arenite is more mature (greater transport distance and/or
more times through the rock cycle) than the Quartz graywacke.

ii) Compositional Maturity

Compositional maturity is reflected by the relative proportion of
physically soft or chemically unstable grains.

The fewer the soft or unstable grains, the more mature the sediment.
The most “mature” sediment would be made up of 100% quartz
grains.

With increased transport and number of times through the rock cycle
the less stable minerals are lost.

The “average” igneous and metamorphic rocks contain 60% feldspars.

The “average” sandstone contains 12% feldspars.

This reflects the fact that many sandstones are made up of particles
that have been through several passes of the rock cycle.
b) Provenance of a sediment
Provenance: where something originated.
The Provenance of a sediment is inferred from aspects of composition
that reflect the source rock and tectonic and climatic characteristics of
the source area for the sediment.

i) Tectonic setting

The source rock of a sediment and the tectonic setting are closely linked:
the tectonic setting determines the relative abundance of different types
of rock that is available for weathering and the production of clastic
sediment.
e.g., An arkosic sandstone (rich in feldspars) would have a source area
that is rich in granites.
A mountain chain adjacent to a convergent margin (e.g., modern Andes)?
An exposed craton (e.g., the Canadian Shield)?
Not foolproof! These are two very different tectonic settings.
e.g., a sandstone with abundant volcanic and low grade metamorphic
rock fragments.
Island arc setting.
Quartz arenite: sedimentary source rocks; uplifted sediments in an
orogenic belt.
Major types of sandstone described by Levin:

Sandstone Environmental Interpretation
Each type of sandstone implies something about depositional history and
environment:
Quartz sandstone implies a long time in the depositional basin. Deposition
typically in tectonically stable, shallow-water environments. Common
sedimentary structures are ripple marks and cross-bedding.
Arkose implies a short time in the depositional basin (because feldspar typically
weathers quickly to clay). Also implies rapid erosion, arid climate, tectonic
activity, steep slopes. Commonly deposited in fault troughs or low areas along
granitic mountains. Often has a pinkish color due to oxidized iron, suggesting
continental deposition.
Graywacke implies a tectonically active source area and depositional basin, with
rapid erosion. Graded bedding is common. Associated with volcanic rocks, shales,
and cherts of deep water origin.
Lithic sandstone is characteristic of deltaic coastal plains, and may be deposited
in nearshore marine environments, swamps, or marshes. Associated with coal
and micaceous shales.
Geologic settings where various
sandstones are deposited.

A = Quartz sandstone
B = Arkose
C = Graywacke
D = Lithic sandstone
ii) Climate

Climate exerts a strong control on the type of weathering that takes place
in the source area of a sediment; this, in turn, influences composition.

Cold, arid climate: predominantly physical weathering, producing
abundant detrital grains (unaltered mineral grains and rock fragments).

Sandstones produced in such settings will be relatively immature,
depending on the source rocks.

Warm, humid climate: chemical weathering predominates.

Unstable minerals removed from the sediment that is produced by
weathering.

Will produce a more mature sediment than a cold climate.
Climate: colder in the north so that physical weathering is important,
producing immature sediment.

Many sediments were produced during glaciation which only breaks
down source rocks by physical processes.

Warmer in the south so that chemical weathering produces a more
mature sediment.
III. Which classification should you use?
This depends on the purpose of the study that you are participating in.

Most studies aimed at determining ancient depositional environments can
classify sandstones on the basis of grain size only.

Studies that aim to reconstruct ancient tectonic settings require a detailed
analysis of the composition of the sandstones.

Some studies require compositional classification in order to understand
the mechanical properties of the sandstone (e.g., if the study aims to
determining excavation costs).
References
1)Tucker, M 1981.Sedimentary Petrology: An Introduction.252 pp, Oxford:Blackwell.
2) Tucker, M. (2001). Sedimentary Petrology.3rd edition, Blackwell publishing
company.
3) Pettijone, F.J., Potter and Siever, R. (1987).sand and Sandstones 2nd edition,
springer-verlag
4) Cheel, R.J. (2005). Introduction to Clastic Sedimentology.
5) Adams,A.E., Mackezie, W.S. & Guilford, C. (1984) atlas of sedimentary Rocks under
the Microscope.

Additional References
Nichols, G. (2009). Sedimentology and stratigraphy. 2nd edition. Blackwell Publishing
company.