Approximately 16,000-20,000 joules of energy are stored in 1 kilogram of wood, depending on the type of wood and its moisture content.
A kilogram of wood contains potential energy in the form of chemical energy. The exact number of joules can vary depending on the type and dryness of the wood, but on average, 1 kilogram of wood contains about 15,000-20,000 joules of energy when burned.
It depends on the type of wood, but on average, a kilogram of wood contains about 15,000-20,000 joules of energy.
On average, wood contains about 16-20 megajoules of energy per kilogram. This energy comes from the combustion of the wood, which releases heat.
On average, wood has a heating value of around 16-20 megajoules per kilogram (MJ/kg). This means that a kilogram of wood contains about 16,000-20,000 joules of energy.
The energy content of wood varies depending on the type and moisture content, but on average, 1 kilogram of wood contains approximately 16-20 megajoules (MJ) of energy.
A kilogram of wood contains potential energy in the form of chemical energy. The exact number of joules can vary depending on the type and dryness of the wood, but on average, 1 kilogram of wood contains about 15,000-20,000 joules of energy when burned.
It depends on the type of wood, but on average, a kilogram of wood contains about 15,000-20,000 joules of energy.
On average, wood contains about 16-20 megajoules of energy per kilogram. This energy comes from the combustion of the wood, which releases heat.
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On average, wood has a heating value of around 16-20 megajoules per kilogram (MJ/kg). This means that a kilogram of wood contains about 16,000-20,000 joules of energy.
The energy content of wood varies depending on the type and moisture content, but on average, 1 kilogram of wood contains approximately 16-20 megajoules (MJ) of energy.
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On average, one kilogram of dry wood contains about 16 to 20 megajoules (MJ) of energy. This can vary depending on the type of wood and its moisture content.
One kilogram of wood would only fill a small part of one cord. One kilogram weighs only a little more than 2 pounds.
The energy liberated by burning the whole match is the weight (0.2grams ?) times heat of combustion of the wood - about 20kJ per gram so a few kilojoules as you almost never burn it completely. Mike
The formula to calculate the energy required is Q = mcΔT, where Q is the energy, m is the mass (2kg), c is the specific heat (1760 J/kg°C), and ΔT is the change in temperature (50-10=40°C). Plugging in the values, we get Q = 2kg * 1760 J/kg°C * 40°C = 140,800 Joules. So, 140,800 Joules of energy must be added to increase the temperature of the wood by 40°C.
The chemical energy in the wood that allows it to burn is transferred to heat, light, and sound energy.