idk if this is an answer but this is what i found in my book.
atomic raduis increases down a group and decreases across a period
Atomic radius is defined as the distance from the nucleus to the outermost electron cloud in an atom. It is often measured as half of the distance between the nuclei of two bonded atoms.
The destructive radius of an atomic bomb can vary depending on its size and yield. A typical atomic bomb might have a blast radius of a few miles, with the most powerful bombs capable of causing devastation over tens of miles.
In visual representations of atomic radius, different colors often indicate varying sizes of atoms or ionic radii across the periodic table. Typically, larger atomic radii are shown in warmer colors like red or orange, while smaller radii are depicted in cooler colors like blue or green. This color coding helps to quickly convey trends in atomic size, such as the increase in atomic radius down a group and the decrease across a period. Overall, the colors provide a straightforward way to visualize and compare atomic sizes.
Nuclear radius increases as you go down and to the left on the periodic table due to effective nuclear charge. Bassicaly, it means that sheilding of electrons by larger atoms having more things in the way that blocks the ability of the nucleus to pull on the electrons, thus the electrons are able to be further from the nucleus and have a larger radius.
That's different for each crystal. A crystal is defined by the way the atoms are arranged in it's structure, so this question is not really answerable for all crystalline structures.
Atomic radius is defined as the distance from the nucleus to the outermost electron cloud in an atom. It is often measured as half of the distance between the nuclei of two bonded atoms.
Please tell me your atomicnumber.You just did 'use atomic number in a sentence' by putting this question on-screen.You could even read the above question and answers aloud, and you will have done it again.I just couldn't believe my eyes when I realized that an atomic number is revealed by the number of protons in the nucleus of an atom!"What is your atomic number?" is NOT a good pick-up line, unless you are speaking to a scientifically-minded person.The atomic number of Helium is 2."The atomic number of Sulfur is 16."(Note that atomic number means the number of protons in the atom, that's why the term proton number is interchangeable with atomic number.)See the related Wikipedia link listed below for more information:
Since a square doesn't normally have a "radius" that we understand, and you haven't defined the term as you're using it, there's no way to answer that question.
Atoms do not have a radius. A helium atom has a nucleus composed of at least two protons and maybe one or two neutrons. A magnesium atom nucleus (and every other atom on the periodic table other than hydrogen) is BIGGER than a helium nucleus. So if you look at it that way...magnesium is larger than helium
One way to determine an ion's radius is by comparing it to a known ion with a similar charge or electron configuration. Another method is to use X-ray crystallography or empirical formulas that take into account the ion's coordination number and ionic radius of the atoms present in the compound.
The destructive radius of an atomic bomb can vary depending on its size and yield. A typical atomic bomb might have a blast radius of a few miles, with the most powerful bombs capable of causing devastation over tens of miles.
In visual representations of atomic radius, different colors often indicate varying sizes of atoms or ionic radii across the periodic table. Typically, larger atomic radii are shown in warmer colors like red or orange, while smaller radii are depicted in cooler colors like blue or green. This color coding helps to quickly convey trends in atomic size, such as the increase in atomic radius down a group and the decrease across a period. Overall, the colors provide a straightforward way to visualize and compare atomic sizes.
Nuclear radius increases as you go down and to the left on the periodic table due to effective nuclear charge. Bassicaly, it means that sheilding of electrons by larger atoms having more things in the way that blocks the ability of the nucleus to pull on the electrons, thus the electrons are able to be further from the nucleus and have a larger radius.
Atomic number = number of protons Atomic mass number = number of protons + number of neutrons Relative mass number = the weighted average mass numbers of the naturally occurring isotopes as compared to C-12 If you delete the atomic number from the mass number you get the number of neutrons. The atomic number is the number of protons and electrons. (They are both the same number.)
for hydrogen it is about 37 pico-meters. larger atoms (larger than H or He) have a second, or even 3, 4, 5, 6, or 7 orbitals of electrons. Francium, #87 has an atomic radius of 270 p-m. Much bigger, but way tiny compared to you.
It depends on the way in which the circle function is defined by the user. It also depends on the way in which the graphing utility implements the instruction.
The electron itself does not have a well-defined "radius" in the same way that classical particles do, as it is considered a point particle in quantum mechanics with no spatial extent. However, in the context of atomic orbitals, the electron in the outermost shell of an atom, such as those in larger atoms like cesium or francium, can be considered to have the largest effective radius due to its greater distance from the nucleus. In this sense, outer electrons in these heavy alkali metals exhibit the largest average distance from the nucleus compared to electrons in smaller atoms.