All non-metals have either 5, 6 or 7 electrons in their octet which makes them suitable to gain electrons to achieve stability. Hence it is difficult for electrons to lose electrons.
Nonmetals are on the left side of the Periodic Table. The more left they are, the less electrons they can lose or give.
The non metals have tendency to gain the electrons to complete its octet and hence achieve stability. These elements do not lose electrons.
Non metals have tendency to gain electrons.They hardly lose electrons.
Nonmetals gain electrons.
Nonmetals gain electrons.
Electron affinity is an elements' ability to attract electrons and is variable for each element. Generally the more electronegative atoms are furthest to the right bottom of the periodic table and ascending to the left the elements lose their electron accepting ability.
All non-metals have either 5, 6 or 7 electrons in their octet which makes them suitable to gain electrons to achieve stability. Hence it is difficult for electrons to lose electrons.
you may find the answer from the periodic tables electron orbiting the nucleus is the answer
no
The number of elements changes periodically because we as humans have the ability to create elements that do not exist in nature. As we create bigger and bigger ones, they are added onto the periodic table of elements.
There is no Group 14. The elements of the group 7A are the most electronegative. Basically, electronegativity is the ability to attract electrons. Group 7A elements, or halogens, need just one more electron to reach stability, and are very reactive. So, they can easily accept that electron. In other words, their ability to attract electrons is the highest.
All or almost all of the nonmetal and metalloid elements that are not noble gases have this property. All the halogens, oxygen, nitrogen, and carbon all form many compounds with other elements as well as polyatomic allotropes of the elements themselves at standard temperature and pressure.
Elements whose atoms contain d orbital electrons are treated differently from other elements in a modern periodic table, largely because when the differentiating electron between two elements differing by a single atomic number is a d orbital electron, this differentiating electron generally goes into an atomic shell with a lower number than the outermost electron shell of the atom. The chemical behavior of elements with d orbital electrons, but not enough of them to fill the shell with the next lower electron shell number than that of the valence s and p orbital electrons in the outermost electron shell, is more difficult to predict than for other elements, because such d orbital electrons sometimes act as valence electrons but sometimes do not. In order to increase the ability of placement of elements in a periodic table to predict the number of valence electrons, it has become customary to use an "extended form" table, in which columns 3 through 12 are reserved for elements that contain at least one d orbital electron in a shell with a lower shell number than the s and/or p orbital electrons in the same atom, but do not contain a full shell of such d orbital electrons. The elements in these columns are called "transition elements". This arrangement of the periodic table leads to the convenient characteristic that the number of valence electrons in a non-transition element is the same as the column number of the element in the periodic table if that column number is less than 4 and is the last digit only of the column number if that number is 13 or more. This method of calculating the number of valence electrons in a non-transition element works also for the first three periods (rows) of the table, which do not contain any transition elements.
Carbon, or C on the periodic table.
The ability of an atom to attract electrons. The most electronegative elements are in the upper right hand corner of the Periodic Table, most notably fluorine.
Electronegativity is the ability of an atom to attract electrons to it, and, by the octet rule, strive to reach noble gas electron configuration. The most electronegative atom is Fluorine, for several reasons- It has the smallest radius, and it only needs to attract one electron to complete its valance shell.
A lot of the common properties of elements come from their atomic structure -- in particular, the arrangement of their electrons. Chemists have determined that electrons in a stable element tend to develop layers of orbits in a predictable pattern. The periodic table is structured to organize the elements along these patterns. The rows of the table shows the basic progression of these electron orbit periods (thus the term "periodic table", while the columns group the elements by the common properties expressed through their electron configurations. For example, the rightmost group of the table is composed of the "noble gases", the most stable of the elements. These elements have complete stable electron groups and are thus nonreactive. With the sixth and seventh rows, the number of electrons that can exist in a layer extends beyond the ability of the table to display them properly. Thus the addition of the Lanthanoid and Actinoid rows below the bottom of the table (named for the first elements in their respective rows).