because the codons will continue the same letters and will match up the same way that it did so it will repeat itself over and over again.
James Watson and Francis Crick are credited with the base pairing rules and DNA structure in general. Erwin Chargaff is credited with the rules of base pairs in that the number of pyrimidines is equal to the number of purines.
n stands for "Nitrogen" on the periodic table of elements
Yes.
Mass
In the atom state (not ionic), yes.
Chargaff
The formula that has an equal number of nitrogen atoms is N2, which represents a nitrogen molecule composed of two nitrogen atoms bonded together.
6.02x1023 particles are in one mole of nitrogen dioxide. One mole of anything, be it nitrogen dioxide of hydrogen monoxide (water), will always equal to 6.02x1023 (a very large number!) of particles. 6.02x1023 particles are in one mole of nitrogen dioxide. One mole of anything, be it nitrogen dioxide of hydrogen monoxide (water), will always equal to 6.02x1023 (a very large number!) of particles.
When working with exponents there are a couple of rules for 1 to remember. Any number that is brought to the power of “one” will always equal that same number or itself. Secondly one at any power is still one. So for two equal bases to have their product be one, they both can equal one.
In a neutral atom, the number of protons is always equal to the number of electrons.
Atomic number is always equal to the number of protons in an atom.
Erwin Chargaff discovered that the amount of adenine is equal to thymine, and the amount of guanine is equal to cytosine in DNA. This led to the discovery of Chargaff's rules, which laid the foundation for Watson and Crick to propose the double helix structure of DNA.
the number 0 is always equal to its opposite
If equal volumes of nitrogen and oxygen are at the same temperature and pressure, then both (the nitrogen and oxygen) will contain the same number of particles
If you multiply them, reciprocals always equal one.
No - in fact it is quite rare
The atomic number reflects the charge number of the nucleus. It is always equal to the number of protons found in the nucleus.