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Mechanics of defects in Carbon nanotubes

Mechanics of defects in Carbon nanotubes. S Namilae, C Shet and N Chandra. Sp3 Hybridization here. Defects in carbon nanotubes (CNT). Point defects such as vacancies Topological defects caused by forming pentagons and heptagons e.g. 5-7-7-5 defect

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Mechanics of defects in Carbon nanotubes

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  1. Mechanics of defects in Carbon nanotubes S Namilae, C Shet and N Chandra

  2. Sp3 Hybridization here Defects in carbon nanotubes (CNT) • Point defects such as vacancies • Topological defects caused by forming pentagons and heptagons e.g. 5-7-7-5 defect • Hybridization defects caused due to fictionalization

  3. Role of defects • Mechanical properties • Changes in stiffness observed. • Stiffness decrease with topological defects and increase with functionalization • Defect generation and growth observed during plastic deformation and fracture of nanotubes • Composite properties improved with chemical bonding between matrix and nanotube • Electrical properties • Topological defects required to join metallic and semi-conducting CNTs • Formation of Y-junctions • End caps • Other applications • Hydrogen storage, sensors etc 1 1Ref: D Srivastava et. al. (2001)

  4. Compute Continuum quantities -Kinetics (,P,P’ ) -Kinematics (,F) -Energetics Use Continuum Knowledge - Failure criterion, damage etc Molecular Dynamics -Fundamental quantities (F,u,v) Mechanics at atomic scale

  5. Stress at atomic scale • Definition of stress at a point in continuum mechanics assumes that homogeneous state of stress exists in infinitesimal volume surrounding the point • In atomic simulation we need to identify a volume inside which all atoms have same stress • In this context different stresses- e.g. virial stress, atomic stress, Lutsko stress,Yip stress

  6. Virial Stress Stress defined for whole system For Brenner potential: Includes bonded and non-bonded interactions (foces due to stretching,bond angle, torsion effects)

  7. BDT (Atomic) Stresses Based on the assumption that the definition of bulk stress would be valid for a small volume  around atom  - Used for inhomogeneous systems

  8. Lutsko Stress - fraction of the length of - bond lying inside the averaging volume • Based on concept of local stress in • statistical mechanics • used for inhomogeneous systems • Linear momentum conserved

  9. Averaging volume for nanotubes • No restriction on shape of averaging volume (typically spherical for bulk materials) • Size should be more than two cutoff radii • Averaging volume taken as shown

  10. Strain calculation in nanotubes • Defect free nanotube  mesh of hexagons • Each of these hexagons can be treated as containing four triangles • Strain calculated using displacements and derivatives shape functions in a local coordinate system formed by tangential (X) and radial (y) direction of centroid and tube axis • Area weighted averages of surrounding hexagons considered for strain at each atom • Similar procedure for pentagons and heptagons Updated Lagrangian scheme is used in MD simulations

  11. Conjugate stress and strain measures • Stresses described earlier  Cauchy stress • Strain measure enables calculation of  and F, hence finite deformation conjugate measures for stress and strain can be evaluated Stress • Cauchy stress • 1st P-K stress • 2nd P-K stress Strain • Almansi strain • Deformation gradient • Green-Lagrange strain

  12. Elastic modulus of defect free CNT -Defect free (9,0) nanotube with periodic boundary conditions -Strains applied using conjugate gradients energy minimization • All stress and strain • measures yield a Young’s • modulus value of 1.002TPa • Values in literature range • from 0.5 to 5.5 Tpa. Mostly • around 1Tpa

  13. Strain in triangular facets • strain values in the triangles are not necessarily equal to applied strain values. • The magnitude of strain in adjacent triangles is different, but the weighted average of strain in any hexagon is equal to applied strain. • Every atom experiences same state of strain. • The variation of strain state within the hexagon (in different triangular facets) is a consequence of different orientations of interatomic bonds with respect to applied load axis.

  14. CNT with 5-7-7-5 defect • Lutsko stress profile for (9,0) tube with type I defect shown below • Stress amplification observed in the defected region • This effect reduces with increasing applied strains • In (n,n) type of tubes there is a decrease in stress at the defect region

  15. Strain profile • Longitudinal Strain increase also observed at defected region • Shear strain is zero in CNT without defect but a small value observed in defected regions • Angular distortion due to formation of pentagons & heptagons causes this

  16. Local elastic moduli of CNT with defects • Type I defect  E= 0.62 TPa • Type II defect  E=0.63 Tpa • Reduction in stiffness in the presence of defect from 1 Tpa • -Initial residual stress indicates additional forces at zero strain • -Analogous to formation energy

  17. Evolution of stress and strain Strain and stress evolution at 1,3,5 and 7 % applied strains Stress based on BDT stress

  18. Bond angle variation • Strains are accommodated by both bond stretching and bond angle change • Bond angles of the type PQR increase by an order of 2% for an applied strain of 8% • Bond angles of the type UPQ decrease by an order of 4% for an applied strain of 8%

  19. Bond angle variation contd • For CNT with defect considerable bond angle change are observed • Some of the initial bond angles deviate considerably from perfect tube • Bond angles of the type BAJ and ABH increase by an order of 11% for an applied strain of 8% • Increased bond angle change induces higher longitudinal strains and significant lateral and shear strains.

  20. Bond angle and bond length effects • Pentagons experiences maximum bond angle change inducing considerable longitudinal strains in facets ABH and AJI • Though considerable shear strains are observed in facets ABC and ABH, this is not reflected when strains are averaged for each of hexagons

  21. Effect of Diameter stiffness values of defects for various tubes with different diameters do not change significantly Stiffness in the range of 0.61TPa to 0.63TPa for different (n,0) tubes Mechanical properties of defect not significantly affected by the curvature of nanotube stress strain curves for different (n,0) tubes with varying diameters.

  22. Effect of Chirality Chirality shows a pronounced effect

  23. Functionalized nanotubes • Change in hybridization (SP2 to SP3) • Nanotube composite interfaces may consist of bonding with matrix • (10,10) nanotube functionalized with 20 Vinyl and Butyl groups at the center and subject to external displacement (T=77K)

  24. Functionalized nanotubes contd • Increase in stiffness observed by functionalizing • Stiffness increase more with butyl group than vinyl group

  25. Summary • Local kinetic and kinematic measures are evaluated for nanotubes at atomic scale • This enables examining mechanical behavior at defects such as 5-7-7-5 defect • There is a considerable decrease in stiffness at 5-7-7-5 defect location in different nanotubes • Changes in diameter does not affect the decrease in stiffness significantly • CNTs with different chirality have different effect on stiffness • Functionalization of nanotubes results in increase in stiffness

  26. Volume considerations • Virial stress • Total volume • BDT stress • Atomic volume • Lutsko Stress • Averaging volume

  27. Bond angle and bond length effects

  28. Bond angle variation contd

  29. Some issues in elastic moduli computation • Energy based approach • Assumes existence of W • Validity of W based on potentials questionable under conditions such as temperature, pressure • Value of E depends on selection of strain • Stress –strain approach • Circumvents above problems • Evaluation of local modulus for defect regions possible

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