Physical Principles of Electron Microscopy: An Introduction to TEM ...

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150 Chapter 5 A backscattered-electron image can be obtained in the environmental SEM, using the detectors described previously. An Everhart-Thornley detector cannot be used because the voltage used to accelerate secondary electrons would cause electrical discharge within the specimen chamber. Instead, a potential of a few hundred volts is applied to a ring-shaped electrode just below the objective lens; secondary electrons initiate a controlled discharge between this electrode and the specimen, resulting in a current that is amplified and used as the SE signal. Examples of specimens that have been successfully imaged in the environmental SEM include plant and animal tissue (see Fig. 5-21), textile specimens (which charge easily in a regular SEM), rubber, and ceramics. Oily specimens can also be examined without contaminating the entire SEM; hydrocarbon molecules that escape through the differential aperture are quickly removed by the vacuum pumps. The environmental chamber extends the range of materials that can be examined by SEM and avoids the need for coating the specimen to make it conducting. The main drawback to ionizing gas molecules during the final phase of their journey is that the primary electrons are scattered and deflected from their original path. This effect adds an additional skirt (tail) to the current-density distribution of the electron probe, degrading the image resolution and contrast. Therefore, an environmental SEM would usually be operated as a high-vacuum SEM (by turning off the gas supply) in the case of conductive specimens that no not have a high vapor pressure. Figure 5-21. The inner wall of the intenstine of a mouse, imaged in an environmental SEM. The width of the image is 0.7 mm. Courtesy of ISI / Akashi Beam Technology Corporation.
The Scanning Electron Microscope 151 5.9 Electron-Beam Lithography Electrons can have a permanent effect on an electron-microscope specimen, generally known as radiation damage. In inorganic materials, high-energy electrons that are “elastically” scattered through large angles can transfer enough energy to atomic nuclei to displace the atoms from their lattice site in a crystal, creating displacement damage visible in a TEM image, such as the point-defect clusters shown in Fig. 4-16. In organic materials, radiation damage occurs predominantly as a result of inelastic scattering; the bonding configuration of valence electrons is disturbed, often resulting in the permanent breakage of chemical bonds and the destruction of the original structure of the solid. This makes it difficult to perform high-resolution microscopy (TEM or SEM) on organic materials, such as polymers (plastics) and impossible to observe living tissue at a subcellular level. However, radiation damage is put to good use in polymer materials known as resists, whose purpose is to generate structures that are subsequently transferred to a material of interest, in a process referred to as lithography. In a positive resist, the main radiation effect is bond breakage. As a result, the molecular weight of the polymer decreases and the material becomes more soluble in an organic solvent. If an SEM is modified slightly by connecting its x and y deflection coils to a pattern generator, the electron beam is scanned in a non-raster manner and a pattern of radiation damage is produced in the polymer. If the polymer is a thin layer on the surface of a substrate, such as a silicon wafer, subsequent “development” in an organic solvent results in the scanned pattern appearing as a pattern of bare substrate. The undissolved areas of polymer form a barrier to chemical or ion-beam etching of the substrate (Section 4.10), hence it acts as a “resist.” After etching and removing the remaining resist, the pattern has been transferred to the substrate and can be used to make useful devices, often in large number. The fabrication of silicon integrated circuits (such as computer chips) makes use of this process, repeated many times to form complex multilayer structures, but using ultraviolet light or x-rays as the radiation source. Electrons are used for smaller-scale projects, requiring high resolution but where production speed (throughput) is less important. Resist exposure is done using either a specialized electron-beam writer or an SEM. In a negative resist, radiation causes an increase in the extent of chemical bonding (by “cross-linking” organic molecules), giving an increase in molecular weight and a reduction in solubility in exposed areas. After development, the pattern is a “negative” of the beam-writing pattern, in the sense that resist material remains in areas where the beam was present (similar to undissolved silver in a black-and-white photographic negative).
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Physical Principles of Electron Mic
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Ray F. Egerton Department of Physic
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Contents Preface xi 1. An Introduct
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Contents ix 7. Recent Developments
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xii Preface textbooks, such as Will
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2 1.1 Limitations of the Human Eye
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4 Chapter 1 parallel beam of light
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6 Chapter 1 Figure 1-3. One of the
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8 Chapter 1 Figure 1-5. Light-micro
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10 Chapter 1 Figure 1-7. Scanning t
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12 Chapter 1 Figure 1-8. Early phot
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14 Chapter 1 Figure 1-10. JEOL tran
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16 Chapter 1 hydrated. But high-ene
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18 Chapter 1 Figure 1-14. Scanning
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20 Chapter 1 Figure 1-16. Photograp
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22 Chapter 1 visible-light photons
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24 Chapter 1 Typically, the STM hea
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Chapter 2 ELECTRON OPTICS Chapter 1
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Electron Optics 29 a c b object len
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Electron Optics 31 � a n 2 ~1.5
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Electron Optics 33 We can define im
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Electron Optics 35 electron source
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Electron Optics 37 symmetry and use
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Electron Optics 39 As we said earli
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Electron Optics 41 2.4 Focusing Pro
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Electron Optics 43 � = [e/(8mE0)
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Electron Optics 45 image plane. Whe
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Electron Optics 47 procedure that i
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Electron Optics 49 The basic physic
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Electron Optics 51 From Eq. (2.7),
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Electron Optics 53 y +V 1 +V 2 -V 2
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Electron Optics 55 point from the o
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58 Chapter 3 3.1 The Electron Gun T
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60 Chapter 3 The rate of electron e
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62 Chapter 3 electron emission curr
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64 Chapter 3 As seen from the right
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66 Chapter 3 � r r s r � (a) (b
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68 Chapter 3 Table 3-2. Speed v and
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70 Chapter 3 where G is a large amp
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72 Chapter 3 The second condenser (
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74 Chapter 3 Figure 3-9 summarizes
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76 Chapter 3 resolution (especially
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78 Chapter 3 The major advantage of
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80 Chapter 3 contrast (for a given
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82 Chapter 3 A more correct procedu
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84 Chapter 3 diffraction pattern (s
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86 Chapter 3 Nowadays, photographic
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88 Chapter 3 A related concept is d
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90 Chapter 3 molecules, imparting a
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92 Chapter 3 Frequently, liquid nit
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94 Chapter 4 -e -e -e -e +Ze Figure
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96 Chapter 4 � (a) elastic z x m
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98 Chapter 4 � b a (a) (b) Figure
Page 108 and 109: 100 Chapter 4 fraction of electrons
Page 110 and 111: 102 Chapter 4 whose composition or
Page 112 and 113: 104 Chapter 4 replica crystallites
Page 114 and 115: 106 Chapter 4 4.5 Diffraction Contr
Page 116 and 117: 108 Chapter 4 remain undiffracted (
Page 118 and 119: 110 Chapter 4 Close examination of
Page 120 and 121: 112 Chapter 4 Unfortunately, the va
Page 122 and 123: 114 Chapter 4 Crystals can also con
Page 124 and 125: 116 Chapter 4 A simple example of p
Page 126 and 127: 118 Chapter 4 High-magnification ph
Page 128 and 129: 120 Chapter 4 At this stage it is c
Page 130 and 131: 122 Chapter 4 All of the above meth
Page 132 and 133: 124 Chapter 4 The procedures outlin
Page 134 and 135: 126 Chapter 5 specimen scan coils o
Page 136 and 137: 128 Chapter 5 functions with m and
Page 138 and 139: 130 Chapter 5 inelastic collisions
Page 140 and 141: 132 Chapter 5 Figure 5-5. Dependenc
Page 142 and 143: 134 Chapter 5 Figure 5-7. (a) Secon
Page 144 and 145: 136 Chapter 5 Because each secondar
Page 146 and 147: 138 Chapter 5 Backscattered electro
Page 148 and 149: 140 Chapter 5 Whereas Ip remains co
Page 150 and 151: 142 Chapter 5 Figure 5-14. Red, gre
Page 152 and 153: 144 Chapter 5 the SE2 and SE3 compo
Page 154 and 155: 146 Chapter 5 just-observable loss
Page 156 and 157: 148 Chapter 5 Section 4-10. Films o
Page 160 and 161: 152 Chapter 5 One example of this p
Page 162 and 163: Chapter 6 ANALYTICAL ELECTRON MICRO
Page 164 and 165: Analytical Electron Microscopy 157
Page 184 and 185: 178 Chapter 7 Figure 7-1. Modified
Page 186 and 187: 180 Chapter 7 7.2 Aberration Correc
Page 188 and 189: 182 Chapter 7 Besides decreasing th
Page 190 and 191: 184 Chapter 7 7.4 Electron Holograp
Page 192 and 193: 186 Chapter 7 There are now many al
Page 194 and 195: 188 Chapter 7 holography could ther
Page 196 and 197: Appendix MATHEMATICAL DERIVATIONS A
Page 198 and 199: Mathematical Derivations 193 A.2 Im
Page 200 and 201: REFERENCES Binnig, G., Rohrer, H.,
Page 202 and 203: INDEX Aberrations, 3, 28 axial, 44
Page 204 and 205: Index 199 EELS, 172 Electromagnetic
Page 206 and 207: Index 201 Principal plane, 32, 80 P
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