In all combustion reactions (other than H2 with O2) CO2(g) and H2O(g) will be produced. CO would NOT be produced, as we are talking about COMPLETE combustion. Why can't the products be in a form of an oxide and a compound gas?
If air is limited during combustion, the process may be incomplete and result in less fuel being burned. This can lead to the formation of carbon monoxide, a toxic gas. Additionally, the amount of heat produced may be reduced, impacting the efficiency of the combustion process.
combustion is the complete oxidation of organic compound into carbon dioxide and water molecules in presence of oxygen gas while oxidation is the addition of oxygen in a compound or with an element the loss of electron from an atom or ion is also oxidation but it is not the combustion.all oxidizing reactions are not combustion reaction.....but all combustion reactions are oxidizing..oxidation reaction does not involve heat.....combustion reactions involve heat....
Combustion reactions that cannot be reversed are those where a fuel combines with oxygen to produce heat and light. Once the fuel is burned, it is converted into new chemical compounds such as water and carbon dioxide, making it impossible to revert back to the original fuel and oxygen.
In photosynthesis, the the electron transport chain is part of the light dependent reactions. The "light independent reactions" are the Calvin-Benson cycle and do not include an electron transport chain, but the Calvin Cycle cannot proceed without the ATP and NADPH produced during the light reactions.
All combustion is exothermic. ( i love pie)
In all combustion reactions (other than H2 with O2) CO2(g) and H2O(g) will be produced. CO would NOT be produced, as we are talking about COMPLETE combustion. Why can't the products be in a form of an oxide and a compound gas?
because during combustion heat energy is released. for example the burning of carbon in air is a combustion reaction but in this process 393.7 K.J/mol energy is released
All 4 are considered oxidation-reduction reactions
O2
All types of combustions are oxidation reactions.
Combustion and single-replacement reactions are also redox reactions. In a combustion reaction, a substance combines with oxygen and releases energy. In a single-replacement reaction, one element replaces another in a compound, resulting in a change in oxidation states.
Oxygen is the reactant compound in all combustion reactions. It serves as the oxidizing agent that combines with the fuel (hydrocarbons) to produce heat, light, and products like carbon dioxide and water.
If air is limited during combustion, the process may be incomplete and result in less fuel being burned. This can lead to the formation of carbon monoxide, a toxic gas. Additionally, the amount of heat produced may be reduced, impacting the efficiency of the combustion process.
All combustion reactions involve the rapid combination of a fuel (usually a hydrocarbon) with oxygen gas to produce heat, light, and typically carbon dioxide and water as byproducts. These reactions are exothermic, meaning they release energy in the form of heat.
Oxygen is the substance common to all combustion reactions. It acts as the oxidizing agent, which combines with a fuel source to release heat and light energy.
To prove that mass is conserved during combustion reactions, you would need to measure the mass of all the reactants before the reaction and the mass of all the products after the reaction. If the sum of the masses of the reactants is equal to the sum of the masses of the products, then mass is conserved. This can be done by using a balance or scale to accurately measure the masses involved.