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![Page 1: Three-Dimensional Internal Source Primary Root Growth Model Brandy Wiegers University of California, Davis Dr. Angela Cheer Dr. Wendy Silk Joint Mathematics.](https://reader035.fdocuments.us/reader035/viewer/2022062518/5697bf931a28abf838c8fa05/html5/thumbnails/1.jpg)
Three-Dimensional Internal Source Primary Root Growth Model
Brandy WiegersUniversity of California, Davis
Dr. Angela Cheer
Dr. Wendy Silk
Joint Mathematics Meetings
January 2008
http://faculty.abe.ufl.edu/~chyn/age2062/lect/lect_15/MON.JPG
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Research Motivation
http://www.wral.com/News/1522544/detail.html http://www.mobot.org/jwcross/phytoremediation/graphics/Citizens_Guide4.gif
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Presentation Outline
Theoretical Background Plant Biology Governing Equations Computational Approach
Existing (External) Root Growth Theory Internal Source Root Growth Theory Future Work
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Photos from Silk’s lab
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How do plant cells grow?
Expansive growth of plant cells is controlled
principally by processes that
loosen the wall and enable it to expand
irreversibly (Cosgrove, 1993).
http://www.troy.k12.ny.us/faculty/smithda/Media/Gen.%20Plant%20Cell%20Quiz.jpg
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What are the rules of plant root growth?
Water must be brought into the cell to facilitate the growth (an external water source).
The tough polymeric wall maintains the shape. Cells must shear to create the needed
additional surface area. The growth process is irreversible
http://sd67.bc.ca/teachers/northcote/biology12/G/G1TOG8.html
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Water Potential, gradient is the driving
force in water movement.
= s + p + m
Gradients in plants cause an inflow of water from the soil into the roots and to the transpiring surfaces in the leaves (Steudle, 2001).
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Hydraulic Conductivity, K
Measure of ability of water to move through the plant
Inversely proportional to the resistance of an individual cell to water influx Think electricity: (Conductance = 1/ Resistance)
A typical value: Kr ,Kz = 1.3x 10-10 m2s-1MPa-1
Value for a plant depends on growth conditions and intensity of water flow
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Relative Elemental Growth Rate, L(z)
A measure of the spatial distribution of growth within the root organ.
Co-moving reference frame centered at root tip.
Marking experiments describe the growth trajectory of the plant through time.
Erickson and Silk, 1980
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L(z) = · (K·) (1) Notation:
Kx, Ky, Kz: The hydraulic conductivities in x,y,z directions
fx = f/x: Partial of any variable (f) with respect to x
In 2d: L(z) = Kzzz+ Krrr + Kz
zz+ Krrrr (2)
In 3d:L(z) = Kxxx+Kyyy+Kzzz
+Kxxx+Ky
yy+Kzzz
(3)
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Experimental Data = -0.2 on Ω Corresponds to growth
of root in growth solution
rmax = 0.5 mm Zmax = 10 mm
Kr, Kz :
1.3 x10-10m2s-1MPa-1
rmax
zmax
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Solving for L(z) =·(K· ) (1)
Generalized Coordinates Finite Difference Approximations
Lijk = [Coeff] ijk (3)
Known: L(z), Kx, Ky, Kz, on ΩUnknown:
The assumptions are the key to the different theories.
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External Source Root Growth Theory Assumptions
The tissue is roughly cylindrical with radius r growing only in the direction of the long axis z.
The growth pattern does not change in time. Conductivities in the radial (Kr) and longitudinal
(Kz) directions are independent so radial flow is not modified by longitudinal flow.
The water needed for primary root-growth is obtained only from the surrounding growth medium.
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*Remember each individual element will travel through this pattern*
External Source Theory
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Multiple Source Root Growth Theory
Adds internal known sources
Doesn’t change previous matrix: L = [Coeff]
Gould, et al 2004
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Multiple Source Root Growth Theory Assumptions
The tissue is roughly cylindrical with radius r growing only in the direction of the long axis z.
The growth pattern does not change in time.
Conductivities in the radial (Kr) and longitudinal (Kz) directions are independent so radial flow is not modified by longitudinal flow.
The water needed for primary root-growth is obtained from the surrounding growth medium AND the phloem sources.
http://home.earthlink.net/~dayvdanls/root.gif
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Multiple Source Theory
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Comparison of Results
3-D Multiple Source Model Results
3-D External Source Model Results
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Sensitivity Analysis: Geometry
r = 0.3mm : 0.5mm :0.7mm
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Summary: Growth Analysis
Radius: increase in radius results in increase of maximum water potential and resulting gradient
Phloem Placement: The further from the root tip that the phloem stop, the more the solution approximates the osmotic root growth model
Hydraulic Conductivity: Increased conductivity decreases the radial gradient
Growth Conditions: Soil vs Water Conditions play an important role in comparing source and non source gradients
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End Goal….
Computational 3-d box of soil through which we can grow plant roots in real time while monitoring the change of growth variables.
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Thank you! Do you have any further questions?
Brandy WiegersUniversity of California, [email protected]://math.ucdavis.edu/~wiegers
My Thanks to Dr. Angela Cheer, Dr. Wendy Silk and everyone who came to my talk today.
This material is based upon work supported by the National Science Foundation under Grant #DMS-0135345
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References John S. Boyer and Wendy K. Silk, Hydraulics of plant growth, Functional Plant Biology 31 (2004),
761:773. C.A.J.Fletcher, Computational techniques for fluid dynamics: Specific techniques for different flow
categories, 2nd ed., Springer Series in Computational Physics, vol. 2, Springer-Verlag, Berlin, 1991. Cosgrove DJ and Li Z-C, Role of expansin in developmental and light control of growth and wall
extension in oat coleoptiles., Plant Physiology 103 (1993), 1321:1328. Ralph O. Erickson and Wendy Kuhn Silk, The kinematics of plant growth, Scientific America 242 (1980),
134:151. Nick Gould, Michael R. Thorpe, Peter E. Minchin, Jeremy Pritchard, and Philip J. White, Solute is
imported to elongation root cells of barley as a pressure driven-flow of solution, Functional Plant Biology 31 (2004), 391:397.
Jeremy Pritchard, Sam Winch, and Nick Gould, Phloem water relations and root growth, Austrian Journal of Plant Physiology 27 (2000), 539:548.
J. Rygol, J. Pritchard, J. J. Zhu, A. D. Tomos, and U. Zimmermann, Transpiration induces radial turgor pressure gradients in wheat and maize roots, Plant Physiology 103 (1993), 493:500.
W.K. Silk and K.K. Wagner, Growth-sustaining water potential distributions in the primary corn root, Plant Physiology 66 (1980), 859:863.
T.K.Kim and W. K. Silk, A mathematical model for ph patterns in the rhizospheres of growth zones., Plant, Cell and Environment 22 (1999), 1527:1538.
Hilde Monika Zimmermann and Ernst Steudle, Apoplastic transport across young maize roots: effect of the exodermis, Planta 206 (1998), 7:19.
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Generalized Coordinates
Converts any grid (x,y,z) into a nice orthogonal grid (ξ,η,ζ)
Uses Jacobian (J) and Inverse Jacobian (J-1)
Photo from Silk’s lab
Fletcher, 1991
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Numerical Methods2nd Order Finite Difference
Approximations
Given general function G(i,j):
G(i,j)ξ = [G(i+1,j) – G(i-1,j)] / (2Δξ) + O(Δξ2)
G(i,j)ξξ = [G(i+1,j) - 2G(i,j) + G(i-1,j)] / (Δξ2) + O(Δξ2)
G(i,j)ξη = [G(i+1,j+1) - G(i-1,j+1) – G(i+1,j-1) + G(i-1,j-1)] / (4ΔξΔη) + O(ΔξΔη)
i , ji -1, j
i , j +1
i +1, j
i , j -1i -1, j -1 i +1, j-1
i +1, j +1i -1, j +1
ηξ
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Grid Refinement & Grid Generation