Yes. Because the Magnesium is more reactive, he gets the nitrate. Look at it this way. There's a boxing match. The prize is the nitrate. Lead is the current winner. The most reactive metal will win the match. Magnesium is more reactive so he wins the nitrate. It's as simple as that!
The reaction between magnesium carbonate and nitric acid involves two types of reactions: a double displacement reaction (also known as a metathesis reaction), where the magnesium and nitrate ions exchange partners to form magnesium nitrate and carbonic acid, and a decomposition reaction, where the carbonic acid breaks down into water and carbon dioxide when heated or left in solution.
Assuming iron's 2 oxidation state.Fe + 2HNO3 --> Fe(NO3)2 + H2Iron (II) nitrate ( also called ferrous nitrate ), a salt, and hydrogen gas.
When magnesium metal wire is heated in open air, an oxidation-reduction reaction takes place between the magnesium and the oxygen in the air. The magnesium is oxidized as the oxygen is reduced. The product of this reaction is magnesium oxide, MgO. Note that this reaction can also be deemed a combustion reaction, which is a specific type of redox reaction which involves the production of heat and sometimes light.
The reaction that takes place when a magnesium ribbon is burnt in air is a combustion reaction. This reaction produces magnesium oxide as a product, and it is exothermic, releasing heat and light.
Reaction that takes place when magnesium burns in air= Magnesium + Oxygen = Magnesium Oxide (magnesia)
The reaction between magnesium carbonate and nitric acid involves two types of reactions: a double displacement reaction (also known as a metathesis reaction), where the magnesium and nitrate ions exchange partners to form magnesium nitrate and carbonic acid, and a decomposition reaction, where the carbonic acid breaks down into water and carbon dioxide when heated or left in solution.
Assuming iron's 2 oxidation state.Fe + 2HNO3 --> Fe(NO3)2 + H2Iron (II) nitrate ( also called ferrous nitrate ), a salt, and hydrogen gas.
The balanced chemical equation for the reaction between magnesium and oxygen to form magnesium oxide is: 2Mg + O2 -> 2MgO.
When magnesium metal wire is heated in open air, an oxidation-reduction reaction takes place between the magnesium and the oxygen in the air. The magnesium is oxidized as the oxygen is reduced. The product of this reaction is magnesium oxide, MgO. Note that this reaction can also be deemed a combustion reaction, which is a specific type of redox reaction which involves the production of heat and sometimes light.
The reaction that takes place when a magnesium ribbon is burnt in air is a combustion reaction. This reaction produces magnesium oxide as a product, and it is exothermic, releasing heat and light.
Reaction that takes place when magnesium burns in air= Magnesium + Oxygen = Magnesium Oxide (magnesia)
Yes, calcium can displace magnesium in certain chemical reactions. This is more likely to happen when calcium is in a higher oxidation state than magnesium, allowing it to take the place of magnesium in a compound or reaction.
I think it's: Mg2 (s) + Fe (NO3)3 (l) -> MgNO2 + Fe3
A displacement reaction, in which the copper dissolves to form copper nitrate and replaces silver ions in the original silver nitrate, reducing the silver ions to metallic silver.
The reaction between milk of magnesia and the acids in your stomach is a neutralization reaction. The magnesium hydroxide in milk of magnesia reacts with the acidic stomach contents to form magnesium chloride and water, thereby neutralizing the acidity.
When a sparkler is lit, the reaction involves the combustion of the metal fuel and the oxidation of the metal. For example, a common reaction in sparklers involves the combustion of magnesium with oxygen to produce magnesium oxide and light and heat energy. The word equation for this reaction is: Magnesium + Oxygen → Magnesium Oxide + Light + Heat.
The chemical reaction between magnesium and oxygen in the flashbulb produces a bright flash of light and heat as energy is released during the formation of magnesium oxide. This reaction is highly exothermic, resulting in the intense burst of light that is characteristic of flashbulbs. The reaction consumes the magnesium and oxygen present in the flashbulb, converting them into magnesium oxide as a product.