They play games
Other elements can acquire a noble gas configuration by either gaining or losing electrons. Elements on the left side of the Periodic Table, such as alkali metals, tend to lose electrons to achieve a noble gas configuration. Elements on the right side of the periodic table, such as halogens, tend to gain electrons to achieve a noble gas configuration. Elements in the middle of the periodic table may gain or lose electrons to acquire a noble gas configuration, depending on the specific element and its properties.
Noble gases have completely filled electronic configuration and hence they are chemically inactive / inert / do not form bond with other elements.
It's fullfill electronic configuration i.e ns2np6 configuration.
They either gain electrons or lose electrons (which ever one that requires the least)
All the elements in their normal state are reactive and unstable. In order to attain stability i.e. a state of minimum energy, they tend to form ions by loosing or gaining electrons. By doing so, they achieve stable electronic configuration or noble gas configuration. However, some elements do not form ions. Instead of that, two such atoms share electrons with each other and achieve this noble gas configuration. At the end, the main reason for attaining a noble gas configuration is to attain max. stability and min. energy.
If you know the name of the gas then look at a periodic table the noble gases are the one in the far right column or group 18 on the table The noble gases are very unreactive to other elements.
Only group 18 elements have noble gas configuration. All other elements lack a noble gas electronic configuration.
Noble gases have completely filled electronic configuration and hence they are chemically inactive / inert / do not form bond with other elements.
It's fullfill electronic configuration i.e ns2np6 configuration.
They either gain electrons or lose electrons (which ever one that requires the least)
All elements tend to react with other elements so as to attain a noble gas electronic configuration in their ions, because such a configuration usually has the lowest energy for a particular atom or ion, other factors being equal. The drive to form such an ion is strongest when the electron configuration of an elemental atom differs from the closest noble gas configuration by only one electron, and this criterion is true for both group and group 17 elements: Group 1 elements can attain a noble gas electron configuration by donating one electron to another atom, and Group 17 elements can attain a noble gas configuration by accepting one electron, thereby filling their valence shell.
All the elements in their normal state are reactive and unstable. In order to attain stability i.e. a state of minimum energy, they tend to form ions by loosing or gaining electrons. By doing so, they achieve stable electronic configuration or noble gas configuration. However, some elements do not form ions. Instead of that, two such atoms share electrons with each other and achieve this noble gas configuration. At the end, the main reason for attaining a noble gas configuration is to attain max. stability and min. energy.
Noble gases have completely filled electronic configuration and hence they are chemically inert (they generally do not form bonds).
noble gases are of very importance in our daily life as we make conclusions about the other valence shell completion of other elements by knowing the noble gases valence electronic configuration
Noble gases have completely filled orbitals. They generally have 8 valence electrons (helium has only 2) and obey octet rule (stable electronic configuration). Hence they are chemically inert (or do not react with other elements).
If you know the name of the gas then look at a periodic table the noble gases are the one in the far right column or group 18 on the table The noble gases are very unreactive to other elements.
The noble gases, located in Group 18 of the periodic table, do not normally react chemically with other elements. They have a stable electron configuration with a full outermost energy level, making them highly unreactive.
Both Li and K lose electrons to get noble gas configuration. Br gains an electron to get noble gas configuration. So K is more likely to form a compound with Br.Potassium is a metal in group 1. It usually forms ionic compounds with other non metallic elements. From these elements, it is more likely to bond with bromine. Recall that lithium is as in the same family as potassium.