First, all the individual power plants of a specific type can be viewed as a single aggregate plant or ensemble and can be observed for its ability to mitigate emissions as it grows. This ability is first dependent on the
energy payback time of the plant. Aggregate plants with a total installed capacity of C_T (in GW) produces: {{NumBlk|:|E_T = t \cdot C_T = t \cdot \sum_{n=1}^N C_n|}} of electricity, where t (in hours per year) is the fraction of time the plant is running at full capacity, C_n is the capacity of individual power plants and N is the total number of plants. If we assume that the energy industry grows at a rate, r, (in units of 1/year, e.g. 10% growth = 0.1/year) it will produce additional capacity at a rate (in GW/year) of After one year, the electricity produced would be The time that the individual power plant takes to pay for itself in terms of energy it needs over its
life cycle, or the
energy payback time, is given by the principal energy invested (over the entire life cycle), E_P, divided by energy produced (or fossil fuel energy saved) per year, E_{ann}. Thus if the energy payback time of a plant type is E_P/E_{ann}, (in years,) the energy investment rate needed for the sustained growth of the entire power plant ensemble is given by the cannibalistic energy, E_{Can}: {{NumBlk|:|E_{Can} = \frac{E_P}{E_{ann}} \cdot r \cdot C_T \cdot t|}} The power plant ensemble will not produce any net energy if the cannibalistic energy is equivalent to the total energy produced. So by setting equation () equal to () the following results: {{NumBlk|:|\frac{E_P}{E_{ann}} \cdot r \cdot C_T \cdot t = C_T \cdot t|}} and by doing some simple algebra it simplifies to: {{NumBlk|:|\frac{E_P}{E_{ann}} = \frac{1}{r}|}} So if one over the growth rate is equal to the energy payback time, the aggregate type of energy plant produces no
net energy until growth slows down. ==Greenhouse gas emissions==