Noble gases are characterized by their complete valence electron shells, making them generally inert and unreactive. However, under specific conditions, they can react with highly electronegative elements like oxygen and fluorine, which can stabilize the resulting compounds. These reactions often require extreme conditions, such as high temperatures or pressures, due to the strong stability of noble gases. Thus, their unique electronic configuration limits their reactivity primarily to these highly reactive elements.
Noble gases are considered inactive and do not react with any other substance/element.
The two abnormal noble gases will be xenon and krypton. Noble gases are generally chemically inert at S.T.P. However, xenon and krypton react with electronegative elements like fluorine and oxygen forming fluorides and oxyfluorides.
Xenon is the noble gas that can react with fluorine. Under specific conditions, xenon forms compounds such as xenon difluoride (XeF2) and xenon tetrafluoride (XeF4). This reactivity occurs despite xenon's general lack of chemical reactivity, which is characteristic of noble gases. Other noble gases, like helium and neon, do not readily react with fluorine.
All noble gases don't react with other elements. Noble or inert gases don't react with other elements because their outer electron shells are completely full. However, the heavier noble gases actually can be forced to react with very electronegative elements like oxygen and fluorine. However, they don't do so readily.
No, they are not. Fluorine, chlorine, and iodine are halogens, meaning they have 7 valence shell electrons. They are the second most nonreactive group of elements, besides the noble gases, which have 8 and do not react at all.
Because fluorine is having the most electronegativity and is the most reactive non metal.
Noble gases are considered inactive and do not react with any other substance/element.
The two abnormal noble gases will be xenon and krypton. Noble gases are generally chemically inert at S.T.P. However, xenon and krypton react with electronegative elements like fluorine and oxygen forming fluorides and oxyfluorides.
Xenon is the noble gas that can react with fluorine. Under specific conditions, xenon forms compounds such as xenon difluoride (XeF2) and xenon tetrafluoride (XeF4). This reactivity occurs despite xenon's general lack of chemical reactivity, which is characteristic of noble gases. Other noble gases, like helium and neon, do not readily react with fluorine.
Noble gases are generally chemically inert at S.T.P. However, at extreme conditions, xenon and krypton react with electronegative elements like fluorine and oxygen forming fluorides and oxyfluorides.
All noble gases don't react with other elements. Noble or inert gases don't react with other elements because their outer electron shells are completely full. However, the heavier noble gases actually can be forced to react with very electronegative elements like oxygen and fluorine. However, they don't do so readily.
No, they are not. Fluorine, chlorine, and iodine are halogens, meaning they have 7 valence shell electrons. They are the second most nonreactive group of elements, besides the noble gases, which have 8 and do not react at all.
No! oxygen does not react with a noble gas because a noble gas does not want any electrons. This means, it's outer shell or valence shell is filled with electrons.
Inert gases, such as helium, neon, and argon, typically do not react with other elements due to their stable electron configuration. However, under certain extreme conditions, such as high temperatures or electrical discharge, they can react with highly reactive elements like fluorine and oxygen to form compounds. The reaction with fluorine and oxygen helps stabilize the electron configuration of the inert gas, making the compound more stable.
Yes, except some noble gases.
if u put fire by it maby I dont really know, do you?
noble gases are those gases which dont react with anything. they are also called inert gases. oxygen is not one of them because it does react; infact, all the burning processes cant take place without oxygen.