when cut, they are all shiny like gold, but then tarnish immediately
Copper metal is less reactive than potassium so it will not react with potassium cyanide.
Potassium reacts vigorously with air to form a yellowish oxide layer. This reaction is highly exothermic and can ignite the potassium. As a result, potassium is typically stored under oil to prevent contact with air.
When potassium reacts with hydrogen gas, potassium hydride (KH) is formed. This reaction is highly exothermic and can release a significant amount of energy. Potassium hydride is a powerful reducing agent and can react violently with water or oxygen.
When iron reacts with air, they form ferric oxide.
It depends. It is most likely potassium chloride and lithium carbonate
When potassium reacts with water, it forms potassium hydroxide and releases hydrogen gas. When potassium reacts with oxygen, it forms potassium oxide.
Potassium
it reacts vigourasly
holaaa lala
It reacts violently, fizzes about on the surface and then: BOOM!!!
Potassium oxidizes immediately when exposed to air. It also reacts violently in water, producing potassium hydroxide and hydrogen gas. The hydrogen gas produced will burn spontaneously, so potassium is always stored in a liquid with which it does not react, such as kerosene.
Copper metal is less reactive than potassium so it will not react with potassium cyanide.
Potassium reacts vigorously with air to form a yellowish oxide layer. This reaction is highly exothermic and can ignite the potassium. As a result, potassium is typically stored under oil to prevent contact with air.
When potassium reacts with hydrogen gas, potassium hydride (KH) is formed. This reaction is highly exothermic and can release a significant amount of energy. Potassium hydride is a powerful reducing agent and can react violently with water or oxygen.
Carbon dioxide (CO2) is removed from the air by potassium hydroxide. Potassium hydroxide reacts with CO2 to form potassium carbonate and water, thereby removing the CO2 gas from the air.
When potassium hydroxide (KOH) reacts with nitric acid (HNO3), potassium nitrate (KNO3) and water (H2O) are formed. The overall reaction can be represented as: KOH + HNO3 → KNO3 + H2O
When sulfur reacts with potassium, they form potassium sulfide. This reaction involves the transfer of electrons from potassium to sulfur, resulting in the formation of ionic bonds. The reaction is exothermic, meaning it releases energy in the form of heat.