A; You are measuring the lattice constant (the distance between planes of atoms) of a sample crystal using X-ray diffraction. The crystal structure is known to be SC or simple cubic. Your X-ray tube produces X-rays with a wavelength of 0.630 nm. You observe the first diffraction peak at an angle of 28.5°. What is the lattice constant of the crystal?
_____???
B: Suppose that at least 21.5 eV is needed to free an electron from a particular element, i.e., to ionize the atom. What is the lowest frequency photon which can accomplish this? And, what is the corresponding wavelength for that photon? Give frequency for answer 1 and wavelength for answer 2.
1b: _____???
2b: _____???
C. Your favorite radio station broadcasts at a frequency of 94.8 MHz with a power of 19.5 kW. How many photons does the antenna of the station emit in each second?
_____???
Please help me solve this and show work! Thanks!
A; You are measuring the lattice constant (the distance between planes of atoms) of a sample...
(i) Given: a cubic crystal. Derive a general relationship between interplanar spacing dhkland lattice constant a, for a plane whose Miller indices are (hkl). (ii) For a BCC iron crystal, the lattice constant a is 0.2866 nm. What is the interplanar spacing for the (220) planes in the crystal. Assume x-rays of wavelength of 0.1790 nm are used for diffraction experiments. (iii) What is the value of the diffraction angle 2 theta from the (220) planes at which diffraction spots...
Q1- The atoms in a crystal are modelled as hard spheres in contact. Calculate the Atomic radius in a fcc lattice with lattice constant 3.6 A Q2- (a) The atomic in a crystal are modelled as hard spheres in constant. Calculate the atomic radius in a fcc lattice with lattice constant 3.6 A. (b) Consider three-dimensional simple cubic lattice with lattice constant a. What is the distance from the center to a corner of the first Brillouin Zone in the...
o adjacent and parallel planes of atoms(Gie. The magnitude of the distance between two adjacent and parn lanar spacing dhkl, is a function of the Miller indices and the interp crystal whose lattice parameter is a (unit cell edge length), the relation araters e relation is as follows: ( For BCC iron compute the interplanar spacing for the (220) set of planes (i) Compute the diffraction angle for the (220) set of planes using Brag's low Given for BCC iron:...
Learning Goal: To understand electromagnetic radiation and be able to perform calculations involving wavelength, frequency, and energy. Several properties are used to define waves. Every wave has a wavelength, which is the distance from peak to peak or trough to trough. Wavelength, typically given the symbol A (lowercase Greek "lambda"), is usually measured in meters. Every wave also has a frequency, which is the number of wavelengths that pass a certain point during a given period of time. Frequency, given...
To understand electromagnetic radiation and be able to perform calculations involving wavelength, frequency, and energy. Several properties are used to define waves. Every wave has a wavelength, which is the distance from peak to peak or trough to trough. Wavelength, typically given the symbol λ (lowercase Greek "lambda"), is usually measured in meters. Every wave also has a frequency, which is the number of wavelengths that pass a certain point during a given period of time. Frequency, given the symbol...
How do you do these? Please show step by step Properties of Waves - Copy Learning Goal: To understand electromagnetic radiation and be able to perform calculations involving wavelength, frequency, and energy. Several properties are used to define waves. Every wave has a wavelength, which is the distance from peak to peak or trough to trough. Wavelength, typically given the symbol λ(lowercase Greek "lambda"), is usually measured in meters. Every wave also has afrequency, which is the number of wavelengths...