The only experiments that do not maintain mass are some nuclear experiments whereby mass becomes energy. All chemical reactions must maintain the conervation of mass.
A closed system would be used to demonstrate the conservation of mass. In a closed system, no mass enters or exits the system, allowing for the observation of mass being conserved through chemical reactions or physical changes.
The law of conservation of mass states that mass is neither created nor destroyed in a chemical reaction; it is simply rearranged. An experiment to demonstrate this is burning a piece of paper: the mass of the paper before burning will be the same as the mass of the ashes, smoke, and gases produced after burning. This experiment confirms that the total mass before and after the reaction remains constant.
Acid-base reactions demonstrate the law of conservation of mass because the total mass of all reactants involved in the reaction will always equal the total mass of all products formed. This is because no atoms are created or destroyed during the reaction, they are simply rearranged into different molecules.
Balanced chemical equations demonstrate the conservation of mass and atoms in a chemical reaction. They show the ratio of reactants and products involved in a reaction and help predict the outcomes of chemical reactions.
The law of conservation of mass, also known as the law of conservation of mass-energy, is based on the experiments of Antoine Lavoisier. This law states that mass or matter cannot be created or destroyed in a chemical reaction, only changed from one form to another.
A closed system would be used to demonstrate the conservation of mass. In a closed system, no mass enters or exits the system, allowing for the observation of mass being conserved through chemical reactions or physical changes.
The law of conservation of mass states that mass is neither created nor destroyed in a chemical reaction; it is simply rearranged. An experiment to demonstrate this is burning a piece of paper: the mass of the paper before burning will be the same as the mass of the ashes, smoke, and gases produced after burning. This experiment confirms that the total mass before and after the reaction remains constant.
the law of conservation of mass.
No
Acid-base reactions demonstrate the law of conservation of mass because the total mass of all reactants involved in the reaction will always equal the total mass of all products formed. This is because no atoms are created or destroyed during the reaction, they are simply rearranged into different molecules.
there will be no mass
THATS WHAT I THINK that "In his experiment he recorded the masses of the starting materials was always same as the total mass of the products". plz tell me if its wrong leo_rizwan@live.com
Lavoisier's experiment with mercury involved heating mercury in a closed system and observing that the total mass remained constant before and after the reaction. This demonstrated that no mass was lost or gained during the process, supporting the law of conservation of mass, which states that mass is neither created nor destroyed in a chemical reaction.
The word to describe HgO in Lavoisier's reaction demonstrating the conservation of mass is "reactant." In this reaction, mercury(II) oxide (HgO) decomposes upon heating into mercury (Hg) and oxygen gas (O2). Lavoisier's experiment illustrated that the total mass of the reactants (HgO) equals the total mass of the products (Hg and O2), thereby confirming the principle of conservation of mass.
According to the law of conservation of mass, mass cannot be created or destroyed in a chemical reaction. Similarly, according to the law of conservation of matter, matter cannot be created or destroyed in a closed system. These laws demonstrate that mass and matter remain constant throughout physical or chemical changes.
contrast the water cycle and law of conservations answer
This experiment is a verification of the law of the conservation of matter. And yes, the mass of all the combustion products would be equal to the mass of the candle and the oxygen it consumed while burning.