The chemical equation for burning fossil fuels such as gasoline is typically represented as:
Hydrocarbon (e.g., C8H18) + Oxygen (O2) -> Carbon Dioxide (CO2) + Water (H2O) + Heat energy
The answer that belongs in the blank space is "oxygen." The chemical equation for the burning of fossil fuels is typically written as: Fossil fuel + oxygen → carbon dioxide + water + heat.
The blank space should be filled with "oxygen." The complete chemical equation for the burning of fossil fuels is fossil fuel + oxygen + carbon dioxide + water + heat.
Burning fossil fuels results in the combustion of hydrocarbons, releasing carbon dioxide, water, and energy. The general chemical equation for burning a hydrocarbon fuel is hydrocarbon + oxygen -> carbon dioxide + water + energy.
The chemical equation for the burning of fossil fuels can be represented by the general formula: ( \text{hydrocarbon (fuel)} + \text{oxygen} \rightarrow \text{carbon dioxide} + \text{water} + \text{heat} ). This represents the combustion reaction where hydrocarbons in fossil fuels react with oxygen to produce carbon dioxide, water, and heat energy.
The general chemical equation for burning fossil fuels such as gasoline is: (C_{n}H_{m} + O_{2} \rightarrow CO_{2} + H_{2}O + heat), where (n) and (m) represent the number of carbon and hydrogen atoms in the fossil fuel molecule, respectively.
The blank space should be filled with "oxygen." The complete chemical equation for the burning of fossil fuels is fossil fuel + oxygen + carbon dioxide + water + heat.
The answer that belongs in the blank space is "oxygen." The chemical equation for the burning of fossil fuels is typically written as: Fossil fuel + oxygen → carbon dioxide + water + heat.
Burning fossil fuels results in the combustion of hydrocarbons, releasing carbon dioxide, water, and energy. The general chemical equation for burning a hydrocarbon fuel is hydrocarbon + oxygen -> carbon dioxide + water + energy.
The chemical equation for the burning of fossil fuels can be represented by the general formula: ( \text{hydrocarbon (fuel)} + \text{oxygen} \rightarrow \text{carbon dioxide} + \text{water} + \text{heat} ). This represents the combustion reaction where hydrocarbons in fossil fuels react with oxygen to produce carbon dioxide, water, and heat energy.
The general chemical equation for burning fossil fuels such as gasoline is: (C_{n}H_{m} + O_{2} \rightarrow CO_{2} + H_{2}O + heat), where (n) and (m) represent the number of carbon and hydrogen atoms in the fossil fuel molecule, respectively.
Carbon dioxide and water vapor belong in the blank space of the chemical equation for the burning of fossil fuels, as the reaction involves the combustion of hydrocarbons in fossil fuels in the presence of oxygen to produce carbon dioxide and water vapor, along with heat energy.
Fossil fuel + Oxygen gas > Carbon dioxide + water + heat (apex)
Carbon dioxide (CO2) belongs in the blank space of the chemical equation, as when fossil fuels burn, they produce carbon dioxide along with water and release heat as a byproduct. The balanced equation is typically represented as Fossil fuel + O2 + H2O + heat -> CO2 + H2O.
In the bank space for the burning of fossil fuels, you would typically see oxygen (O2) as the reactant needed for combustion to occur. The balanced equation would be: Fossil fuel + O2 → CO2 + H2O + energy.
The chemical equation for the combustion of fossil fuels, like gasoline, can be represented by CxHy + O2 -> CO2 + H2O. This equation shows that when fossil fuels are burned, they react with oxygen to produce carbon dioxide and water vapor.
The chemical energy in fossil fuels is released through combustion, which involves burning the fuel in the presence of oxygen to produce heat, light, and various byproducts such as carbon dioxide and water.
A spark of energy is required to initiate the chemical reaction of burning a fossil fuel because it provides the activation energy needed to break the bonds in the molecules of the fuel. Another name for this spark of energy is the ignition energy.