Part 2
The Kα X-ray emission line of tungsten occurs at λ=0.021 nm. The energy difference between K and L levels in this atoms is about
17
Jun
The Kα X-ray emission line of tungsten occurs at λ=0.021 nm. The energy difference between K and L levels in this atoms is about The Kα X-ray emission line of tungsten occurs at λ=0.021 nm. The energy difference between K and L levels in this atoms is about June 17, 2021 Category: Cengage NEET by [...]
Electrons with de- Broglie wavelength λ fall on the target in an X- rays tube . The cut off wavelength of the emitted X- rays is
17
Jun
Electrons with de- Broglie wavelength λ fall on the target in an X- rays tube . The cut off wavelength of the emitted X- rays is Electrons with de- Broglie wavelength λ fall on the target in an X- rays tube . The cut off wavelength of the emitted X- rays is June 17, 2021 [...]
Which one of the following statement is wrong in the context of X- rays generated from X- rays tube ?
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Jun
Which one of the following statement is wrong in the context of X- rays generated from X- rays tube ? Which one of the following statement is wrong in the context of X- rays generated from X- rays tube ? June 17, 2021 Category: Cengage NEET by C.P Singh , Chapter 13 - X Rays [...]
For a structural analysis of crystals, X-rays are used because
17
Jun
For a structural analysis of crystals, X-rays are used because For a structural analysis of crystals X-rays are used because June 17, 2021 Category: Cengage NEET by C.P Singh , Chapter 13 - X Rays , Part 2 ,
The intensity of X-rays form a Coolidge tube is plotted against wavelength as shown in the figure. The minimum wavelength found is λc and the wavelength of the Kα line is λk. As the accelerating voltage is increased
17
Jun
The intensity of X-rays form a Coolidge tube is plotted against wavelength as shown in the figure. The minimum wavelength found is λc and the wavelength of the Kα line is λk. As the accelerating voltage is increased number of electrons striking the target per second is. The potential difference applied to an X-ray tube [...]
Electrons with energy 80keV are incident on the tungsten target of an X – rays tube , k- shell electrons of tungsten have ionization energy 72.5 keV X – rays emitted by the tube contain only.
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Jun
Electrons with energy 80keV are incident on the tungsten target of an X – rays tube , k- shell electrons of tungsten have ionization energy 72.5 keV X – rays emitted by the tube contain only. Electrons with energy 80keV are incident on the tungsten target of an X - rays tube k- shell electrons [...]
In a Coolidge tube, the potential difference across the tube is 20 kV, and 10 mA current flows through the voltage supply. Only 0.5 % of the energy carried by the electrons striking the target is converted into X-rays. The X-ray beam carries a power of
17
Jun
In a Coolidge tube, the potential difference across the tube is 20 kV, and 10 mA current flows through the voltage supply. Only 0.5 % of the energy carried by the electrons striking the target is converted into X-rays. The X-ray beam carries a power of and 10 mA current flows through the voltage supply. [...]
The binding energy of the innermost electron in tungsten is 40 keV. To produce characteristic X – rays using a tungsten target in an X – rays tube the potential difference V between the cathode and the anti – cathode should be
17
Jun
The binding energy of the innermost electron in tungsten is 40 keV. To produce characteristic X – rays using a tungsten target in an X – rays tube the potential difference V between the cathode and the anti – cathode should be number of electrons striking the target per second is. The potential difference applied [...]
If the potential difference applied across a Coolidge tube is increased.
17
Jun
If the potential difference applied across a Coolidge tube is increased. If the potential difference applied across a Coolidge tube is increased. June 17, 2021 Category: Cengage NEET by C.P Singh , Chapter 13 - X Rays , Part 2 ,
The potential difference applied to an X-ray tube is 5 kV and the current through it is 3.2 mA. Then, number of electrons striking the target per second is.
17
Jun
The potential difference applied to an X-ray tube is 5 kV and the current through it is 3.2 mA. Then, number of electrons striking the target per second is. number of electrons striking the target per second is. The potential difference applied to an X-ray tube is 5 kV and the current through it is [...]