The greatest amount of diffraction occurs when the size of the opening or obstacle is comparable to the wavelength of the wave. This is known as the principle of diffraction, where larger obstructions cause greater bending of the waves around them.
The greatest acceleration will occur in the object with the smallest mass. This is because acceleration is inversely proportional to mass when a constant force is applied (F = ma). The object with the smallest mass will experience the greatest acceleration when the same force is applied.
For lens systems with circular apertures, the diffraction limited resolution can be calculated by knowing the f/# of the lens and the wavelength of light (lambda) traveling through the optical system. The diffraction limit is the maximum spatial resolution of a theoretically "perfect" lens. No further resolution will be available beyond this theoretical value. d.l. = 1/(lambda * f/#) Keep the units in mm and you will end up with a resolution limit result in units of line pairs per millimeter. e.g. - f/2.4 lens, 0.00055mm (green light) -> 1(2.4 * 0.00055mm) = 757 line pairs per millimeter. Remember that one line pair is a dark and bright line together. JFS - Optikos Corporation.
The answer is volume. Volume is a measure of the amount of 3-dimensional space that an object occupies.
The force would be greatest when the object has the greatest mass and acceleration, following Newton's second law which states F = ma. Initially, the force could also be greatest during impact or collision when the object experiences a sudden change in momentum.
For acceleration to occur, there must be a change in velocity, meaning either the speed or direction is changing. A net force must also be acting upon the object, according to Newton's second law of motion.
John F Lakner has written: 'X-ray diffraction cell for Debye-Scherrer camera operating at hydrogen pressures up 255 MPa' -- subject(s): X-rays, Diffraction, Hydrogen
The greatest acceleration will occur in the object with the smallest mass. This is because acceleration is inversely proportional to mass when a constant force is applied (F = ma). The object with the smallest mass will experience the greatest acceleration when the same force is applied.
When the moon is at positions a, c, or f (new moon, first quarter, third quarter), neap tides will occur. Neap tides have the least difference between high and low tide levels. When the moon is at position d (full moon), spring tides will occur, which have the greatest difference between high and low tide levels.
Mercury has the greatest temperature extremes of and planet.
F. Raynaud has written: 'Electron diffraction evidence for the ordering of excess nickel atoms by relation to stoichiometry in nickel-rich B'-NiAl formation of a nickel-aluminum (Ni2Al) superlattice' -- subject(s): Aluminum alloys, Electron diffraction, Nickel alloys, Stoichiometry, Vacancies (Crystal defects)
Cl and F
It occurs between -4 to 14 degrees F. Remember, F!!
Call F the final amount and P the principal. Then F = P(1+i)n F/(1+i)n = P
The element that has the greatest electromagnetivity is Flourine, F, with 3.98.
# include<stdio.h> main() { int a,b,c; print f("enter the values of a,b,c"); scan f("%d%d%d",&a,&b,&c); if((a>b)&&(a>c)) print f("Greatest value is a =%d",a); else if((b>a)&&(b>c)) print f("Greatest value is b=%d",b); else print f("Greatest value is c=%d",c); }
A spring tide will occur
For lens systems with circular apertures, the diffraction limited resolution can be calculated by knowing the f/# of the lens and the wavelength of light (lambda) traveling through the optical system. The diffraction limit is the maximum spatial resolution of a theoretically "perfect" lens. No further resolution will be available beyond this theoretical value. d.l. = 1/(lambda * f/#) Keep the units in mm and you will end up with a resolution limit result in units of line pairs per millimeter. e.g. - f/2.4 lens, 0.00055mm (green light) -> 1(2.4 * 0.00055mm) = 757 line pairs per millimeter. Remember that one line pair is a dark and bright line together. JFS - Optikos Corporation.