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Transcript
Bragg’s Law & SEM/TEM By Nathan Brummel Objectives • Bragg’s Law • X-ray Emission • Powder Diffraction • Diffractometer • The Electron Microscope Bragg’s Law In 1913 William Lawrence Bragg & William Henry Bragg came up with Bragg’s Law Nobel Prize in physics in 1914 Bragg’s Law is simple & Elegant Confirmed the existence of real particles at the atomic scale Sir William Bragg William Henry Bragg nλ = 2dsinθ nλ = 2dsinθ X-ray Emission The X-ray Tube • Breaking radiation “Bremsstrahlung” is produced from the decelerating incident-beam particle • Results in the production of x-rays Classification of Materials • Incoming x-ray is sufficiently large • Characteristic x-rays can be discharged • Leads to characteristic peaks • Peaks are from inter-orbital transitions within the target atom as the electron jumps from a higher energy band to a lower energy band to fill vacancy left due to the characteristic x-ray that is emitted Powder Diffraction X-ray Diffraction The Problem & Solution • Problem: • Polychromatic radiation is perfect for mono-crystalline structures • Solution: • Monochromatic radiation Debye & Scherrer/Hall • Diffraction is inevitable in powder • • orientations present chance for constructive interference is maximized Diffractometer High precision Can determine lattice parameter Small ∆es in composition can be detected The Electron Microscope •For complex/smaller dimension materials •Much higher potential •Higher energy •Lower Vacuum •SEM •Scanning Electron Microsope •Versatility by way of electronic circuitry •TEM •Transsmission Electron Microscope •Enhanced for high spatial resolution SEM • High voltage source is used to accelerate electrons • Electromagnetic lenses are used to focus the electrons • An aperture adjust focal length • Vacuum is required • Bulk materals can be used •Backscattering at high angles •Produces topographical contrast and undulation in the surface •Efficiently differentiate between regions of high and low atomic concentration •Bad for amorphous samples TEM TEM • Similar to SEM • Needs higher vacuum and voltage potential • Needs extremely thin samples • a few atoms think Lens System • System consists of anywhere from 100 to 1000 lenses • They are coupled into groups • Objective lens •high spatial resolution images and diffraction •Condenser lens controls illumination and magnification •Causes electrons to travel in a helical trajector Modes • Image mode • focusing on the front plane producing a magnified image • Diffractino mode • focusing on the back focal plane • diffraction pattern that correctly corresponds to a family of crystallographic planes within the sample Bright Field vs. Dark Field Preparation of Samples • Slice very thin ( mm in thickness) • Place into a micro lathe to file down the center point, at which, it is almost trasparent • Place into an ion mill until a hole starts to appear • Area around hole is thin enough for use in a TEM Conclusion • Bragg’s Law • X-ray Emission • Powder Diffraction • Diffractometer • The Electron Microscope
