Glacial landscapes

Question 1

importance of glaciers

Answer 1

• landscape development
• climate change and glacier response
• water resources (consumption/hydroelectricity using sub-glacial water)
• glacial hazards

Question 2

causes of glaciation and deglaciation

Answer 2

• swing from icehouse to greenhouse worlds (100’s of millions of years)
• mid term fluctuations are superimposed on the longer term cycles (100s of thousands of years) northern hemisphere glacier build up, advance and retreat
• short term flucturatiosn are superimposed on the mid term cycles (10s to 100s of years) waxing and waning of established glaciers

Question 3

Factors forcing glaciation

Answer 3

isolation: Incidence of Solar radiation

Question 4

Milankovitch cyclicity

Answer 4

• 23ka precession, angle
• 41ka obliquity, wobble of earths axis - enhanced seasonal differences
• 100ka eccentricity, shape of orbit around the sun, circular to elliptical

Question 5

short term controls on ice extent

Answer 5

• thermohaline circulation changes
• solar activity
• volcanic activity

Question 6

glaciation through time

Answer 6

• icehouse to greenhouse worlds (snowball earth hypothesis)

- Proterozoic: 2.3 - 2.2 billion years ago

Question 7

Geological time

Answer 7

From ancient glaciation to modern

• Quaternary period , the ice age
• glacial cold stages interspersed with warm interglacials
• last interglacial: Eemian 125,00 years ago

Question 8

Summary of last glaciation

Answer 8

• 2.6 million years of expansion and contraction of glaciers and ice sheets
• today glaciers cover 10% of the earth with their occurrence being influenced by a number of factors
• glaciers provide a valuable resource
• changes in glacial extent affect the earths climate
• changes in the earths climate affect glacial extent
• helped shape the landscape of much pf the mid-latitudes on timescales of 10s to millions of years

Question 9

Glacier morphology and movement importance

Answer 9

• characteristics of ice determines glacier temp
• temp controls processes of erosion, transport and deposition
• climate controls annual gains and loss of snow and ice
• gains and losses influence ice movement (advance and retreat)

Question 10

formation of glacial ice

Answer 10

ice forms by a 5 stage continuous process
- snowflakes
- compaction
- grains
- firn (somewhere between snow and ice)
- glacial ice
(rate of transformation varies with climate: temperature and precipitation regimes

Question 11

firn to ice transformation

Answer 11

this is the stage at which the accumulated snow has the density to form a coherent pack of ice which can least year round

Question 12

nature of glacier ice

Answer 12

• ice is a polycrystalline material. crystal size and shape vary with depth and history
• glaciers comprise ice, liquid water, air and debris
• important attributed of ice are temperature, density and melting point

Question 13

glacier morphology

Answer 13

• classified according to shape and relationship with underlying topography
• ice sheets, ice caps, ice fields, ice streams (all dominate topography)
• outlet glaciers, valley glaciers, Piedmont glaciers, cirque glaciers (all constrained by topography)
• marine ice masses: ice shelves

Question 14

first order classification

Answer 14

• ice sheet and ice cap unconstrained by topography (cirque/corrie/cwn)
• glaciers constrained or controlled by topography
• marine glaciers: floating

Question 15

how do glaciers move?

Answer 15

combination of:

• driving forces
• stress
• resisting forces
• strain

Question 16

glacier motion: driving forces

Answer 16

• surface slope

- weight of ice; basal ice conditions (frozen or slightly melted)

Question 17

Resisting forces

Answer 17

• strength of glacier ice

- contract between glacier and bed (resisting force may vary dependent on nature of the bed)

Question 18

Acumulation and ablation

Answer 18

equals mass balance

Question 19

stress

Answer 19

measure of how hard a material is being pushed or pulled by external forces

Question 20

strain

Answer 20

measure of the amount of deformation occurring as a result of the applied stress `

Question 21

type of glacier motion

Answer 21

• internal ice deformation 1: creep
• internal ice deformation 2: faulting (crevasses)
• sliding of ice over bedrock/sediment (Water film)
• sub glacial bed deformation (Weak substrate)

Question 22

cold-based ice

Answer 22

• ice which is frozen
• no water present at the glacier bed
• low erosive potential
• protects the bed
• selective erosion
• most common in polar regions

Question 23

warm based ice

Answer 23

• water present ice-bed boundary
• high erosive potential (Slides over/erodes the bed)
• most common in temperate regions
• thicker ice masses
• still below zero

Question 24

pressure melting point

Answer 24

• as pressure increases, the temperature at which the ice becomes liquid is lowered
• controls are: atmospheric conditions, geothermal heat flux, frictional heat

Question 25

ways water enters a glacier

Answer 25

• englacial channels
• snow melt percolation
• firn
• water saturation zone
• subglacial sediments and channels
• moulin
• crevasses
• groundwater flow
• supraglcial melt water channels

Question 26

temperate glacier

Answer 26

warm ice except seasonally warmed and cooled surface layer

Question 27

cold glacier

Answer 27

entirely cold ice

Question 28

polythermal glacier

Answer 28

both warm and cold ice

Question 29

erosive processes vary depending on the type and composition of the ice

Answer 29

• ice thickness,
• temperature (warmed by friction of movement and geothermal heat)
• water content
  affect erosion considerably

Question 30

erosion

Answer 30

• removal of rock or sediment
• polishing of rock
• widening, deepening or lengthening pre-exising topographic features (glacial action)

Question 31

factors that influence rates of erosion

Answer 31

• bedrock composition
• unconsolidated sediment
• friction
• ice flow
• incorporation of sediment into the ice

Question 32

Key concept of stresses

Answer 32

shear stress (force acting on the bed) and resistance forces (friction and cohesion)
SS>RF = erosion
RF>SS = deposition

Question 33

stress and resistance

Answer 33

• uneven bed: the more uneven , the more the ice has to adapt to be able to flow around protuberances
• erosion and deposition are both the result of competing stresses in the subglacial environment

Question 34

large scale erosion

Answer 34

• Quarrying: breaking or fracturing the rock (loading, pressure release)
• Plucking: removal of large blocks of rock from valley sides or bottom by glacial action (freeze thaw activity)

Question 35

small scale erosion

Answer 35

• Abrasion: the rubbing down of rock surfaces surrounding the glacier by debris held within the ice
• Polishing: smoothing of rock surfaces by very fine-grained materiel held within the ice

Question 36

Erosion controls summary

Answer 36

• Strength of the materials making up the bed measured as frictional strength and cohesion
• For unconsolidated materials (sediment), water content is important
• Low  cohesion low
• High  cohesion/resistance higher
• For solid bedrock the internal structure and orientation of structures is critical
• Bedding planes
• Weathering planes
• Faults

Question 37

micro-scale

Answer 37

• forms parallel to ice movement
• superficial erosion: abrasion
• generally less than 1cm deep, and up to several metres long
• close inspection show rough base and sides
• size proportional to rock roughness, load applied
• generally widen down glacier
• orientation may vary over short distances

Question 38

meso-scale erosional forms

Answer 38

• streamline bedrock features (Whaleback, Roche Moutonees; crag and tails)
• steep up slope (resistant bedrock)
• smooth down-slope
• ice stream around obstacle
• quarrying and abrasion with increased pressure to form land forms

Question 39

macro-scale erosional forms

Answer 39

• cirques: compound, cirque complexes, staircase cirques, cirque troughs
• glacial valleys

Question 40

Process of cirque formation

Answer 40

• initial nivation hollow - nivation cirque - glacial cirque
• critical threshold (ice is thick enough to achieve internal deformation and basal sliding )
• floor is abraded and quarried
• headwall retreats by; freeze thaw, mass failure, rock slope failure
• enlargement is backwards and downswards
• theories of formation state that enlargement occurs over time

Question 41

Troughs and Fjords

Answer 41

• these are amongst the largest erosional landforms one earth
• difficult to attribute all erosion to glaciers. most are multi-process products (Glacial, periglacial, paraglacial, weathering, fluvial erosion)
• largest are 1000km long, 40km wide and 3.4km deep

Question 42

erosion summary

Answer 42

• Bedrock is eroded by glacial ice (e.g. quarrying (plucking) and abrasion) and/or subglacial meltwater (dependent on subglacial water pressures).
• The processes of erosion are inherently linked with glacier dynamics and glacier motion e.g. sliding, abrasion and quarrying.
• Erosional processes, therefore, reflect glacier dynamics and the patterns of stresses and pressures across the subglacial environment.
• Scale of erosive features varies from microscopic to entire landscapes (Striae to Roches Moutonées, Glacial Valleys)

Question 43

as a glaciers mass balance adjusts

Answer 43

Englacial environment
• Ice: creep, faulting, folding
• Water: percolation, flow
Subglacial environment
• Sliding via meltwater
• Sediment Deformation
• Erosion (Abrasion, Plucking, Quarrying, 
•Deposition
Proglacial environment
• Sediment deposition/accumulation/accretion
• Erosion by meltwater
• Periglacial features

Question 44

entertainment and transport

Answer 44

• sediment is incorporated at many stages
  Accumulation zone
• supraglacial, remains unaltered
• englacial/subglacial becomes rounded through abrasion
  Ablation zone
• transport times redueced
• transport passively as supraglacial sediment
• sediment also transported subglacially
• conveyor belt of sediment

Question 45

Supraglacial transport of debris

Answer 45

Glacier surface transport
• This is SUPRAglacial transport
• Common sources of debris are: Rock fall, Avalanche, Debris flow, Airborne debris (aeolian sands, volcanic ash)
• Rock fall is most common and voluminous, but only if
there are rock surfaces above the ice
• Not prevalent on ice sheets or ice caps

Question 46

Basal transport of debris

Answer 46

• debris is derived from abrasion processes and quarrying/plucking
• entrainment can be of:
  • individual clasts
  • agglomerations of rock flour
  • large rafts of unconsolidated debris
• there are 2 sub-zones of basal debris transport:
  1) traction zone (contact between ice and its bed)
  2) dispersed zone (sediment becomes incorporated in ice)

Question 47

Traction zone

Answer 47

• very active
• comminution processes ensure that debris undergoes significant change with distance of transport
• debris characteristics which change include; texture, roundness, fabric

Question 48

compostion of debris in a glacier

Answer 48

Sorted:
- key processes; aeolian (wind), fluvial (Flowing water), still water
- not deposited by glacial ice itself
Unsorted
- key process; ploughing, crushing, plucking,, rock/debris flows, dumping
- deposition by glacial ice can occur

Question 49

Tills

Answer 49

characteristics depend on glacial history
- source
- transport
- depositional environment
Types: lodgement, deformation, sub-glacial meltout, supra-glacial meltout, flow and indurated till

Question 50

classification of glacial deposition landforms

Answer 50

• aligned (drumlins)
• ice marginal (End moraines and kame/kettle topography)
• fluvioglacial (rivers under and in front of ice)
• glaciolacustrine (lake systems in front of the ice)

Question 51

Drumlins

Answer 51

• positive forms
• typically smooth
• oval/elliptical (approx. aligned along orientation of flow)
• blunt upstream end and tapered downstream ent
• 5-50m in height
• 10-3000m long
• composed of sediments
• occur in fields or swarms in lowland locations

Question 52

Active drumlin field in Iceland

Answer 52

• Boulton-Menzies theory 1) sediment accumulated and is built up and shaped at the bed of the glacier, formed by deformation of soft bed, accretion of hills
• Shaw theory 2) formed by mega floods, erosion of hollows

Question 53

Boulton-Menzies theory of drumlin formation

Answer 53

• subglacial deformation and accretion theory
• weaker sediment (Finer grained, less well drained) deform more easily
• stronger sediment forms core, slow deformation
• weaker sediment transported around the cores, rapid deformation

Question 54

Shaw Hypothesis for drumlin formation

Answer 54

• meltwater theory
• similar morphology to small sale erosional features, therefore similar processes
• horseshoe vortices from down steam of obstacles
• rock drumlins, formed by erosion
• sediment drumlins, formed when flood is hyper concentrated with sediment

Question 55

problems associated with shaw drumlin theory

Answer 55

• lack of evidence
• drumlins revealed by ice since LIA have not been associated with this type of melt water mechanism
• large floods in Iceland today do not produce drumlinised forms

Question 56

Kame topography

Answer 56

• mound or ridge between glacier and hillside
• supra-glacial, glaciofluvial deposition at ice margin
• have flatter, regularly sloping surface
• less chaotic sedimentology (bedding present)
• more sand in composition (due to fluvial formation)

Question 57

Kettle topography

Answer 57

• depression or hollow
• subsidence following melt of ice within kame sediment
• often formed during ice down wastage

Question 58

multiple ridges

Answer 58

• glacier change from positive to negative mass balance
• advance and retreat
• pushing up previously deposited moraine ridge

Question 59

Moraines

Answer 59

• can be annual features (push forward winter/surge, retreat back in summer)
• up to 100s m high
• following plan form of the snout
• steep proximal slope
• gentle distal slope

Question 60

ice margin

Answer 60

• if ice margin is stable a ridge will accumulate

- is ice margin is activity retreating debris will be spread over a wide are and may be no definite land forms

Question 61

Ice marginal moraine ridges

Answer 61

• ridge of debris, often till, but not always
• processes involved in deposition vary (sliding, rolling, squeezing, bulldozing)
• extreme limit of ice usually marked by (terminal moraine)
• still stand during retreat marked by recessional or retreat moraines