Introduction to Soils and Soil Resources

1
Introduction to Soils and Soil Resources

• 2001

2
Contact the Instructor

• Edith Olson
• 705 General Services Building
• Phone 492-8743
• E-mail ecolson_at_ualberta.ca

3
Conduct

• No cheating
• No copying
• Academic offense
• Penalties

4
Timeline

• So much material, so little time
• Break at 750 resume at 810
• Module one weeks one to four
• Module two weeks five to eight

5
Course Objectives

• Terminology
• Characteristics
• Processes
• Soil resources

6
Learn About

• Soil formation
• Physical properties of soil
• Chemical properties of soil
• Soil as a home for life
• Affects of human activities on soil

7
Course Format

• Lectures
• Assignments
• Labs
• Discussion

8
Text Book

• Introduction to soil science and soil resources.
  The pedosphere and its dynamics. A systems
  approach to soil science. Noorallah Juma. 1999

9
Lab Manual

• Introduction to soil
• Science and Soil Resources Lab
• Manual (ready soon!)

10
Recommended Reading

• The Nature and Properties of Soils. (Any
  edition) Nyle C. Brady and Ray R. Weil.1996

11
Recommended Reading

• The Canadian System of Soil Classification.
  Agriculture and Agri-food Canada. 1998.
• Soil Science Principles and Practices. Third
  edition. R. L. Hausenbuiller.1985

12
Web Sites

• For soils ERM information go to
• Http//www.soils.rr.ualberta.ca/SoilsERM
• For online access to the textbook go to
• pedosphere.com

13
Important Dates in 2001

• Labs Feb 10 and March 10
• Module 1 exam Feb 10
• Module 2 exam March 10
• 9 am to 1 pm or noon to 4 pm

14
Exams

• 30 multiple choice questions
• 30 _at_ 2 marks each worth 60
• 3 or 4 questions requiring short answers
• worth 40
• one hour exam
• Dont panic. You can do it!

15
Assignment of Marks

• Module exams 2 _at_ 30 60
• Assignments 2 _at_ 5 10
• Assignments 5 _at_ 4 20
• Hands-on labs 2 _at_ 5 10

16
Written work

• Use pen or word processing for assignments
• Show all working
• Neat

17
Module 1
18
Objectives

• The global view of soil
• Fundamental soil properties
• Identifying and describing soil
• Soil distribution in the landscape
• Canadian Soil Classification System
• Legal land survey
• Soil survey and mapping

19
Material for Module 1

• Sections 1 to 5 and 12 of the textbook
• Website
• Human Interaction with the Terrestial Surface
• The Soils of Alberta tutorial
• Soils in Specific Canadian Ecozones

20
Soil and History

• Civilization is based on the soil
• Destroy the soil, destroy civilization
• Preserve the soil, preserve life

21
Uses of Soil

• Engineering
• Agriculture
• Reclamation

22
Soil supports life

• Micro and Macro organisms
• Reservoir for nutrients and water
• Protection from temperature
• Gas exchange

23
Definition

• Skin of the Earth
• Three phase system Solid, Liquid and Gas
• Natural Body

24
(No Transcript)
25
Soil

• Made from parent material
• Influenced by climate
• Influenced by relief
• Home to micro and macro organisms
• Changes over time

26
Regolith

• Unconsolidated residues resulting from the
  chemical and physical weathering of rocks

27
Weathering

• The breakdown of rocks and minerals by chemical
  and physical processes.
• Minerals make rocks - rocks weather back into the
  minerals of which they were made.

28
Rate of weathering

• Depends on
• the size and composition of the minerals
• soil pH
• temperature
• biotic activity
• water and air content

29
Parent Material

• Unconsolidated material
• The material from which soil is formed
• Weathered chemically and physically

30
Soil Components

• Mineral
• Organic
• Water
• Air

31
(No Transcript)
32
Soil Horizon

• A distinct layer of soil
• Approximately parallel to the surface
• Differs from the layer above and below it

33
Master horizons

• A
• B
• C
• O
• LFH

34
A horizon

• Mineral
• At or near the surface
• zone of removal of materials in suspension
• zone of removal of materials in solution
• zone of maximum accumulation of organic carbon
• or a combination of these zones

35
B horizon

• Mineral
• enrichment of silicate clay, iron,aluminum or
  humus
• prismatic or columnar structure with stains
  associated with exchangeable sodium
• altered by hydrolysis, reduction, or oxidation to
  change structure or colour

36
C horizon

• Mineral
• relatively unaffected by pedogenic processes that
  are taking place in the A and B horizons.
• Could be gleyed
• Could have carbonates and soluble salts

37
O horizon

• Organic
• More than 17 organic matter
• Found in organic soils
• Common at the surface of wet mineral soils

38
LFH

• Organic
• Found under forest vegetation
• May have only L
• Spongy
• Decaying organic forest litter

39
Soil Profile

• Two dimensional vertical section of a soil
• Example a road side cutting

40
Soil Profile
A horizon
B horizon
C horizon Parent Material

• Rock

41
(No Transcript)
42
Soil as an Open System

• Soil interacts with the environment around
• and within it to exchange
• water
• gases
• minerals
• energy
• nutrients

43
(No Transcript)
44
(No Transcript)
45
Texture, Structure and Colour
46
Soil Texture

• The percentages of sand, silt and clay in a soil.
• Soil assigned to a texture class
• Does not include the organic matter

47
Texture Triangle

• Tells us what the soil texture is.
• Determined by percent sand, silt and clay.
• Hand and lab analysis to get texture.

48
(No Transcript)
49
Particle size ranges
50
Texture

• Tells us something about the physical and
  chemical properties of the soil
• Examples
• Clay soil will shrink and swell
• Clay soil and cation exchange
• Sandy soil wont hold water

51
Coarse and Fine soil

• A coarse soil has a high percentage of sand
• Gritty feel
• A fine soil has a high percentage of clay
• Smooth feel

52
Texture and physical properties

• How much pore space?
• Affects how much air and water the soil can
  hold.
• Arrangement of the particles
• Affects how well the soil packs.
• Implications for plant roots.

53
Bulk density

• Bulk density is the proportion of solid in a
  given volume
• Due to aggregation, clay has less solid in a
  given volume than sand
• So clay has more pore space than sand and can
  hold more water or air.

54
Texture and chemical properties

• Adsorption
• Surface area
• Clay has more surface area than sand
• More area available for chemical reactions and
  for the adsorption of water

55
Structure

• The combination of the primary particles of sand,
  silt and clay into secondary particles such as
  peds, blocks, aggregates and columns.

56
Type of Structure

• The type of structure is determined by how
  distinct the arrangement of particles is, the
  size of the arrangement and the shape.

57
Types of soil structure

• aggregates
• blocks
• plates
• prisms
• columns
• structureless

58
Grade of structure

• How obvious is the structure?
• Very - strong
• Not very - medium
• Hard to see - weak

59
Size of structure

• How big is the arrangement of the particles?
• Measure it.
• Use a size chart
• Use a subjective term to describe it such as fine
  or medium or coarse.

60
Type of Structure

• The shape
• Platy
• Granular
• Blocky
• Prismatic
• Structureless

61
Block like structure
62
Block Like Structure
63
Block Like Structure
64
Plate like structure
65
Type Prismlike
Credit CSSC Pedosphere.com
66
Type Prismlike
Credit CSSC Pedosphere.com
67
Type Prismlike
Credit CSSC Pedosphere.com
68
Type Structureless
Credit CSSC Pedosphere.com
69
Examples

• Strong, medium, subangular blocky
• Weak, fine, granular
• Medium, coarse, platy
• Single grain
• Massive

70
Importance of structure

• Makes the soil porous
• Affects physical,
• chemical and
• biological processes

71
Structure and physical processes

• resistance or susceptibility to erosion
• infiltration and runoff
• ability of the soil to conduct water
• drainage and aeration

72
Structure and nutrient cycling

• leaching
• ability to weather the soil
• ion exchange
• gas exchange
• mineralization and immobilization

73
Structure and carbon cycling

• Root turnover and exudation
• microbial activity and turnover
• decomposition
• respiration
• humification
• accumulation of organic matter

74
Bulk density

• Symbol Db or ?b
• bulk density mass of oven dry soil
• volume of soil and pores
• Units are g cm-3 or Mg m-3

75
Measuring bulk density

• Oven dry the soil at 105oC
• Record the oven dry weight
• Measure the volume occupied by the soil
• calculate bulk density as
• weight of oven dry soil
• volume of soil

76
Particle density

• The density of the particles themselves
• Not the bulk density
• Does not take into consideration the pore space
• Always less than bulk density due to smaller
  volume

77
Particle density

• Mass per unit volume of the soil particles
• Symbol Dp or ?p
• particle density mass of particles
• volume of particles
• Units are g cm-3 or Mg m-3

78
Particle density

• For calculations, we assume that the particle
  density is
• 2.65 g cm-3
• which is the same as
• 2.65 Mg m-3

79
Typical bulk densities
80
Pore space

• Bulk density and pore space related
• Pore space expressed as a
• Pore space (1-Db/Dp) x 100
• Pore space also called porosity

81
(No Transcript)
82
(No Transcript)
83
Aggregation

• Aggregates consist of mineral particles and
  organic material which are intimately bound.
• Aggregates also contain air water
• Aggregation of particles reduces bulk density
  because micropores are present within soil
  aggregates.

84
Pore space and texture

• Clay soils have smaller pore spaces than sand.
• Clay soils have more pore spaces than sand.
• Clay soils have more total pore space than sand.
• Combination of intra-aggregate and
  inter-aggregate pore space.

85
Texture, Db and porosity
86
Porosity/Structure
87
Porosity and microbes

• Less pore space, less room for microbes
• Harder to move around
• Water limitations
• Compact soil has no room for microbes

88
Conclusions

• As clay content increases, pore space increases
  and bulk density decreases due to heterogeneity
  in soil particle size and arrangement.
• As clay content increases, pore space also
  increases, but the size of individual pores
  decreases.

89
Conclusions

• Soil structure results in the development of soil
  pores.
• Water, gases, solutes and clay particles move
  through pores.
• Soil structure controls movement of water, ions,
  solutes, clay and anthropogenic compounds.

90
Soil Colour

• Hue. The colour
• Colour value. Lightness of a colour.
• Colour chroma. Purity of a colour.

91
Munsell

• Tells us the colour of a soil
• Numerical and descriptive
• Gives a hue, value and chroma
• Munsell notation is H V/C

92
Munsell Color System

• A color designation system specifying the
  relative degrees of the three simple variables of
  color
• hue dominant spectral color
• value lightness of color
• chroma purity of color
• Red (5R 6/14)

93
Colour and soil properties

• Distinguishes soil horizons
• Relates to the soil organic matter
• Relates to the minerals
• Relates to the moisture regime
• Need to know if soil was dry, moist or wet when
  the colour was assigned

94
Soil Color

• Used to distinguish soil horizons
• Mineral and organic components impact color to
  soil
• Colloidal materials impact soil color
• Humus is black
• Iron oxides are red
• Reduced iron is blue green

95
Soil Color

• Soil color reflects regime of water and air in
  soil.
• Reduced soils have soluble iron and manganese
  compounds
• Oxidized soils have iron and manganese oxides
• Example of iron nail

96
Soil Color

• Soil color in surface horizons is correlated with
  organic matter content nutrient supplying power
• Quartz imparts light color
• Feldspars are predominantly red
• Soil color needs to be used with soil texture and
  structure

97
Conclusions for Soil Color

• Soil color can be described qualitatively and
  quantitatively under specified moisture
  conditions.
• Soil color indicates regime of water and air in
  soil.
• Soil color in surface horizons is correlated to
  soil organic matter content.

98
Next week

• Review week 1.
• Relationship of climate to vegetation in Alberta
• Types of Parent materials found in Alberta

99
Are you still awake??