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Northwestern University Rod Ruoff Nanotechnology Fracture Mechanics of One- Dimensional Nanostructures.

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Presentation on theme: "Northwestern University Rod Ruoff Nanotechnology Fracture Mechanics of One- Dimensional Nanostructures."— Presentation transcript:

1 Northwestern University Rod Ruoff Nanotechnology Fracture Mechanics of One- Dimensional Nanostructures

2 Northwestern University Rod Ruoff Nanotechnology Carbon Nanotube Source SEM image of powdered cathode deposit core material with 30-40% MWCNT content from MER Corp. SEM image of separated MWCNTs on a silicon wafer, after fractionation. Arc-grown Multi-wall Carbon Nanotubes (MWCNTs) from MER Corp. AZ. were studied in this work. A simple fractionation process was used to remove some impurities and increase nanotube concentration.

3 Northwestern University Rod Ruoff Nanotechnology Testing Tool: Nanomanipulator A home-built nanomanipulator is used to perform mechanics study inside vacuum chamber of an scanning electron microscope (SEM). X-Y stage Piezo bimorph Z stage Cantilever Holder Specimen/ Cantilever Holder X-Y Stage Z-stage Piezoelectric Actuator Nanomanipulator inside vacuum chamber of FEI Nova 600 SEM (Ruoff group) Home-built nano-manipulator

4 Northwestern University Rod Ruoff Nanotechnology Nanoscale Tensile Test Experimental Setup X-Y Stage rigid cantilever soft cantilever Z Stage Tensile Test Schematic L L+  s Atomic force microscope (AFM) cantilevers are used as manipulation tools and force-sensing elements. MWCNT

5 Northwestern University Rod Ruoff Nanotechnology In situ Clamping - EBID Electron beam induced deposition (EBID) is the process of using a high- intensity electron beam to deposit structures on a scanned surface. EBID is commonly used to make clamps in situ inside SEM. A CNT in contact with an AFM tip, before and after EBID clamping EBID principle Hydrocarbon molecules EBID clamp Exposure area

6 Northwestern University Rod Ruoff Nanotechnology “Sword-in-sheath” Fracture Outer shell Inner shells Cross-sectional area: D   : inter-layer separation of graphite, 0.34 nm Multi-wall carbon nanotubes fracture in a “sword-in sheath” manner during tensile test.

7 Northwestern University Rod Ruoff Nanotechnology MWCNT Diameter Measurement (a) AFM chip holder model AFM cantilevers (c) Gatan TEM straining holder (model 654) (d) SEM and TEM images of a MWCNT fragment attached to an AFM tip. (b) An AFM chip in the AFM chip holder Cantilever holders were designed to hold a shortened AFM chip for nanotube diameter measurement in TEM.

8 Northwestern University Rod Ruoff Nanotechnology Stress & Strain Measurements The whole tensile testing process was recorded by taking SEM images at each loading step.

9 Northwestern University Rod Ruoff Nanotechnology MWCNT Tensile Testing Result Fracture Strength Elastic Modulus Average elastic modulus: ~ 910 GPa

10 Northwestern University Rod Ruoff Nanotechnology Multiple Loading (Tube #6) Test # Gauge Length (  m) Breaking Force (nN) Tensile Strength (GPa) Failure Strain (%) Elastic Modulus (GPa) 14.08220 21  1.41.8  0.31200  210 23.75240 23  1.41.9  0.31250  210 33.46420 41  2.63.0  0.21230  130 (1)(2)(3)

11 Northwestern University Rod Ruoff Nanotechnology Nanoparticle Chain Aggregates Breaking Force: 42  25 nN Tensile Strength: 40 -100 MPa Elastic Modulus : 200 - 600 MPa Particle Contact Force: 8  4 nN Tensile Testing Stretching a chain Contact Force Measurement Carbon nanoparticle chain aggregates Nanoparticle diameter: 25-35 nm Chain length: ~ 2  m

12 Northwestern University Rod Ruoff Nanotechnology Nonlinearity: Large Deflection + Misalignment where F x =F  sin  and F y =F  cos  (Transformation; Converting to elliptic integrals) F(k),F( ,k) complete and incomplete elliptic integral of first kind. k and  1 are obtained from angle  0 with following relationships: L F x y yy 00 xx  s FyFy FxFx (x,y)

13 Northwestern University Rod Ruoff Nanotechnology Experimental Data Analysis Slope  0 (degree) Loading Angle  (degree) Applied Load Vertical Deflection  y Linear (  N) Analytical (  N) Error (%) Measured (  m) Linear (  m) Analytical (  m) 11.036.825.329.714.842.942.242.3 17.45.523.524.95.668.770.870.3 9.2242.020.823.913.030.632.232.3 11.62.019.419.61.041.440.540.4 15.024.327.631.412.152.952.452.3 AFM cantilevers were used as force-sensing elements in our nanoscale tensile testing experiments on templated carbon nanotubes inside SEM. Large deflection of the cantilever beam was encountered in the tests along with non-ideal alignment of the specimens. The linear analysis underestimated the applied load up to 15 %.

14 Northwestern University Rod Ruoff Nanotechnology Error in Linear Estimation Normalization Linear analysis Analytical analysis

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