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

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60 Chapter 3 The rate of electron emission can be represented as a current density Je (in A/m 2 ) at the cathode surface, which is given by the Richardson law: Je = A T 2 exp(� �/kT) (3.1) In Eq. (3.1), T is the absolute temperature (in K) of the cathode and A is the Richardson constant (� 10 6 Am -2 K -2 ), which depends to some degree on the cathode material but not on its temperature; k is the Boltzmann constant (1.38 � 10 -23 J/K), and kT is approximately the mean thermal energy of an atom (or of a conduction electron, if measured relative to the Fermi level). The work function � is conveniently expressed in electron volts (eV) of energy and must be converted to Joules by multiplying by e =1.6 � 10 -19 for use in Eq. (3.1). Despite the T 2 factor, the main temperature dependence in this equation comes from the exponential function. As T is increased, Je remains very low until kT approaches a few percent of the work function. The temperature is highest at the tip of the V-shaped filament (farthest from the leads, which act as heat sinks), so most of the emission occurs in the immediate vicinity of the tip. Tungsten has a high cohesive energy and therefore a high melting point (� 3650 K) and also a low vapor pressure, allowing it to be maintained at a temperature of 2500 � 3000 K in vacuum. Despite its rather high work function (� = 4.5 eV), �/kT can be sufficiently low to provide adequate electron emission. Being an electrically conducting metal, tungsten can be made into a thin wire that can be heated by passing a current through it. In addition, tungsten is chemically stable at high temperatures: it does not combine with the residual gases that are present in the relatively poor vacuum (pressure > 10 -3 Pa) sometimes found in a thermionic electron gun. Chemical reaction would lead to contamination (“poisoning”) of the emission surface, causing a change in work function and emission current. An alternative strategy is to employ a material with a low work function, which does not need to be heated to such a high temperature. The preferred material is lanthanum hexaboride (LaB6; � = 2.7 eV), fabricated in the form of a short rod (about 2 mm long and less than 1 mm in diameter) sharpened to a tip, from which the electrons are emitted. The LaB6 crystal is heated (to 1400 � 2000 K) by mounting it between wires or onto a carbon strip through which a current is passed. These conducting leads are mounted on pins set into an insulating base whose geometry is identical with that used for a tungsten-filament source, so that the two types of electron source are mechanically interchangeable. Unfortunately, lanthanum hexaboride becomes poisoned if it combines with traces of oxygen, so a better vacuum (pressure < 10 -4 Pa) is required in the electron gun. Oxide cathode materials
The Transmission Electron Microscope 61 (used in cathode-ray tubes) are even more sensitive to ambient gas and are not used in the TEM. Compared to a tungsten filament, the LaB6 source is relatively expensive (� $1000) but lasts longer, provided it is brought to and from its operating temperature slowly to avoid thermal shock and the resulting mechanical fracture. It provides comparable emission current from a smaller cathode area, enabling the electron beam to be focused onto a smaller area of the specimen. The resulting higher current density provides a brighter image at the viewing screen (or camera) of the TEM, which is particularly important at high image magnification. Another important component of the electron gun (Fig. 3-1) is the Wehnelt cylinder, a metal electrode that can be easily removed (to allow changing the filament or LaB6 source) but which normally surrounds the filament completely except for a small (< 1 mm diameter) hole through which the electron beam emerges. The function of the Wehnelt electrode is to control the emission current of the electron gun. For this purpose, its potential is made more negative than that of the cathode. This negative potential prevents electrons from leaving the cathode unless they are emitted from a region near to its tip, which is located immediately above the hole in the Wehnelt where the electrostatic potential is less negative. Increasing the magnitude of the negative bias reduces both the emitting area and the emission current Ie. Although the Wehnelt bias could be provided by a voltage power supply, it is usually achieved through the autobias (or self-bias) arrangement shown in Figs. 3-1 and 3-6. A bias resistor Rb is inserted between one end of the filament and the negative high-voltage supply (�V0) that is used to accelerate the electrons. Because the electron current Ie emitted from the filament F must pass through the bias resistor, a potential difference (IeRb) is developed across it, making the filament less negative than the Wehnelt. Changing the value of Rb provides a convenient way of intentionally varying the Wehnelt bias and therefore the emission current Ie. A further advantage of this autobias arrangement is that if the emission current Ie starts to increase spontaneously (for example, due to upward drift in the filament temperature T ) the Wehnelt bias becomes more negative, canceling out most of the increase in electron emission. This is another example of the negative feedback concept discussed previously (Section 1.7). The dependence of electron-beam current on the filament heating current is shown in Fig. 3-3. As the current is increased from zero, the filament temperature eventually becomes high enough to give some emission current. At this point, the Wehnelt bias (�IeRb) is not sufficient to control the emitting
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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
Page 18 and 19: 8 Chapter 1 Figure 1-5. Light-micro
Page 20 and 21: 10 Chapter 1 Figure 1-7. Scanning t
Page 22 and 23: 12 Chapter 1 Figure 1-8. Early phot
Page 24 and 25: 14 Chapter 1 Figure 1-10. JEOL tran
Page 26 and 27: 16 Chapter 1 hydrated. But high-ene
Page 28 and 29: 18 Chapter 1 Figure 1-14. Scanning
Page 30 and 31: 20 Chapter 1 Figure 1-16. Photograp
Page 32 and 33: 22 Chapter 1 visible-light photons
Page 34 and 35: 24 Chapter 1 Typically, the STM hea
Page 36 and 37: Chapter 2 ELECTRON OPTICS Chapter 1
Page 38 and 39: Electron Optics 29 a c b object len
Page 40 and 41: Electron Optics 31 � a n 2 ~1.5
Page 42 and 43: Electron Optics 33 We can define im
Page 44 and 45: Electron Optics 35 electron source
Page 46 and 47: Electron Optics 37 symmetry and use
Page 48 and 49: Electron Optics 39 As we said earli
Page 50 and 51: Electron Optics 41 2.4 Focusing Pro
Page 52 and 53: Electron Optics 43 � = [e/(8mE0)
Page 54 and 55: Electron Optics 45 image plane. Whe
Page 56 and 57: Electron Optics 47 procedure that i
Page 58 and 59: Electron Optics 49 The basic physic
Page 60 and 61: Electron Optics 51 From Eq. (2.7),
Page 62 and 63: Electron Optics 53 y +V 1 +V 2 -V 2
Page 64 and 65: Electron Optics 55 point from the o
Page 66 and 67: 58 Chapter 3 3.1 The Electron Gun T
Page 70 and 71: 62 Chapter 3 electron emission curr
Page 72 and 73: 64 Chapter 3 As seen from the right
Page 74 and 75: 66 Chapter 3 � r r s r � (a) (b
Page 76 and 77: 68 Chapter 3 Table 3-2. Speed v and
Page 78 and 79: 70 Chapter 3 where G is a large amp
Page 80 and 81: 72 Chapter 3 The second condenser (
Page 82 and 83: 74 Chapter 3 Figure 3-9 summarizes
Page 84 and 85: 76 Chapter 3 resolution (especially
Page 86 and 87: 78 Chapter 3 The major advantage of
Page 88 and 89: 80 Chapter 3 contrast (for a given
Page 90 and 91: 82 Chapter 3 A more correct procedu
Page 92 and 93: 84 Chapter 3 diffraction pattern (s
Page 94 and 95: 86 Chapter 3 Nowadays, photographic
Page 96 and 97: 88 Chapter 3 A related concept is d
Page 98 and 99: 90 Chapter 3 molecules, imparting a
Page 100 and 101: 92 Chapter 3 Frequently, liquid nit
Page 102 and 103: 94 Chapter 4 -e -e -e -e +Ze Figure
Page 104 and 105: 96 Chapter 4 � (a) elastic z x m
Page 106 and 107: 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 (
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110 Chapter 4 Close examination of
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112 Chapter 4 Unfortunately, the va
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114 Chapter 4 Crystals can also con
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116 Chapter 4 A simple example of p
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118 Chapter 4 High-magnification ph
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120 Chapter 4 At this stage it is c
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122 Chapter 4 All of the above meth
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124 Chapter 4 The procedures outlin
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126 Chapter 5 specimen scan coils o
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128 Chapter 5 functions with m and
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130 Chapter 5 inelastic collisions
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132 Chapter 5 Figure 5-5. Dependenc
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134 Chapter 5 Figure 5-7. (a) Secon
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136 Chapter 5 Because each secondar
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138 Chapter 5 Backscattered electro
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140 Chapter 5 Whereas Ip remains co
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142 Chapter 5 Figure 5-14. Red, gre
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144 Chapter 5 the SE2 and SE3 compo
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146 Chapter 5 just-observable loss
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148 Chapter 5 Section 4-10. Films o
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150 Chapter 5 A backscattered-elect
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152 Chapter 5 One example of this p
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Chapter 6 ANALYTICAL ELECTRON MICRO
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Analytical Electron Microscopy 157
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178 Chapter 7 Figure 7-1. Modified
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180 Chapter 7 7.2 Aberration Correc
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182 Chapter 7 Besides decreasing th
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184 Chapter 7 7.4 Electron Holograp
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186 Chapter 7 There are now many al
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188 Chapter 7 holography could ther
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Appendix MATHEMATICAL DERIVATIONS A
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Mathematical Derivations 193 A.2 Im
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REFERENCES Binnig, G., Rohrer, H.,
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INDEX Aberrations, 3, 28 axial, 44
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Index 199 EELS, 172 Electromagnetic
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Index 201 Principal plane, 32, 80 P
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