Engineering role of vegetation: Slope stability problems

CECHR Annual Symposium 2016

Engineering role of vegetation: Slope stability problems Dr Anthony K. Leung a.leung@dundee.ac.uk, Lecturer in Civil Engineering Date: 24th February 2016

Background Rainfall-induced shallow slope failure (< 2 m) Traditional engineering methods of shallow slope stabilisation

Soil nailing

Shotcreting

Mok Tse Che Road, Sai Kung

Anderson Road

http://mandjdrilling.com/?ID=30&SubID=50



High embodied carbon and energy



Accelerating climate change  Increased instability problems  Vicious circle! Low CO2, environmentally friendly techniques are needed

 2

http://hkss.cedd.gov.hk/hkss/chi/studi es/lic/Html_04/index04.htm

http://www.workinginhongkong.com/gallery/pub lic/mid%20levels%20hong%20kong%20photos/sh otcreted%20slope.JPG

Background Slope bioengineering method – revegetation Before

Tree Vehicles Transpiration

Live pole responsible for mechanical reinforcement

Potential slip surface Fibrous roots responsible for root-water uptake to induce suction

After 

Environmentally and ecologically friendly  Atheistically-pleasing; enhance biodiversity; carbon offset



Mechanical effects of root reinforcement Hydrological effects of transpiration



http://hkss.cedd.gov.hk/hkss/eng/green/green/greening.htm

3

Infrastructure slope

Vegetation research at Dundee 

Mechanical effects of root reinforcement on slope stability Rooting for sustainable performance (Recently funded by EPSRC) Seismic performance of vegetation slopes (Funded by Chinese Scholarship Council) Influence of plant roots on soil resistance to earthquake-induced liquefaction (Funded by Leverhulme Trust)

  

Centrifuge modelling 3-D printed root model 4

100

(A) Excluded

Soil matric suction, kPa

80

Vegetation research at Dundee

Ue

Ps

60

Cm

 

Ca

Sv

Hydrological effects of plant transpiration 40

Lv f = y0+a*x y0 -22.2911

BioEngineered Plant-Integrated Cover (BioEPIC) slope Effects of plant-induced suction on slope hydrology, stability and deformation? 20

Ee

Ia

0

a 103.5919 r2 0.95 p-value <0.0001

Bs

-20

0.0

0.2

0.4

0.6

0.8

Soil matric suction, kPa Penetration resistance, MPa

1007

5

>10 native species for testing their induce suction

6 80 5

Ps

60 4

r2 0.85 p-value 0.0008

Ca

Cm

Ca

Sv

Sv

403

Ps

Lv Lv

Cm

2 20 1

f = y0+a*x y0 -22.2911 a 103.5919

Ee

Ia Ia

0 0

(A) (B)

f = y0+a*x y0 -0.9398 a 5.9372

Excluded Excluded Cs Ue Ue Cs

1.0

Ee

r2 0.95 p-value <0.0001

Bs Bs

-20 0.0 0.0

7

a



Cs

6

0.2 0.2

0.4 0.4

0.6

Root:shoot ratio, g g f = y0+a*x y -0.9398

0.8

1.0 1.0

-1

(B)

Centrifuge modelling Development of new artificial root systems Transpiration Schefflera heptaphylla

Rhodomyrtus tomentosa 0.72

Melastoma sanguineum

Leaf

0.78

0.75

0.15

0.79

(After Leung, 2014)

Root

(a)

0.375 0.09 (Outer diameter)

0.75

0.09 (Outer diameter)

0.75

0.1

0.1

Connected to vacuum source

(b)

0.375 0.09 (Outer diameter) (c)

Suction controlled system (Ng et al. 2014)

High AEV porous filter

(d)

Ng, C.W.W., Kamchoom, and Leung, A. K. 2015. Centrifuge modelling of the effects of root geometry on the transpirationinduced suction and stability of vegetated slopes. Landslides. In press. 6

Centrifuge modelling of “vegetated� soil slope Rainfall intensity = 70mm/hr

15-g

Nozzle

Vacuum delivery panel

Nozzle

6.39

P1 P2 P3

1.50

P4

0.3 0.3 0.6 0.6 1.2 1.2 2.3 2.3

Elevation 7

15 artificial roots

450

(Silty sand, RC=95%) 2.70

1.73

6.39

5.25

1.50

Artificial root

1.2 1.2 0.75 0.75 0.45 0.45

Instrumented plane

Side

0.75

0.15

0.15

0.1 0.75

0.78 0.75

0.78

0.78

Centrifuge modelling of “vegetated” soil slope (After Leung, 2014) (After Leung, 2014) (After Leung, 2014) Root Root suction Root Effects of root geometry on “transpiration”-induced

(a)

Tap

0.1

0.1

0.1

Heart

P1 P2 P3

Plate

P1 P2 P3

P4

P5

0.75

0.75 0.75

0.09 0.375 (Outer diameter) 0.09 (Outer diameter)

0.75

0.09 (Outer diameter)

0.75 0.75

0.1

0.1 0.1

Connected to Connected to Connected to vacuum source vacuum source vacuum source Suction Suction Suction controlled controlled controlled system system system (Ng et al. (Ng et al. (Ng et al. 0.090.375 0.09 0.09 0.375 0.09 0.3750.375 0.375 2014) 2014) 2014) (Outer (Outer (Outer (Outer 0.09 diameter) diameter) diameter)0.09 diameter) High AEV (Outer High AEV (Outer High AEV (a) (b) (b) (c) (c) porous diameter)(a) (b)(c)diameter) porous porous (d) (d) (d filter filter filter

P1 P2 P3

P4

P6

P5

P4

P6

P5

P6

Ng, C.W.W., Kamchoom, and Leung, A. K. 2015. Centrifuge modelling of the effects of root geometry on the transpirationinduced suction and stability of vegetated slopes. Landslides. In press. 8

Thank you for your attention!