Not exact matches
Potential applications have been recently reported for energy nano - generators, systems based on the pyroelectric
effect, and
electric energy storage systems like batteries,» explains Agustín Pérez.
When an
electric field is applied, the electrons move from an energetically higher lying
potential well to an energetically lower lying
potential well via the quantum mechanical tunneling
effect.
The nanogenerator relies on the triboelectric
effect to harness energy from the changing
electric potential between the pavement and a vehicle's wheels.
But in such experiments, the
effects of the local
electric potential and the
electric field are convoluted, making it very hard to understand the results.
Although it doesn't have as much twist or any rear - steer at its disposal, the NSX and its comparably swift - shifting nine - speed auto pull off exactly the same trick, mitigating the
potential lag - boost
effects of its twin turbos with immediate throttle response, the right gear and the full weight of the
electric motors» precisely vectored torque.
electric power plants are: (1) survey and assess the capacity, cost, and location of
potential depleted gas and oil wells that are suitable CO -LCB- sub 2 -RCB- repositories (with the cooperation of the oil and gas industry); (2) conduct research on the feasibility of ocean disposal, with objectives of determining the cost, residence time, and environmental
effects for different methods of CO -LCB- sub 2 -RCB- injection; (3) perform an in - depth survey of knowledge concerning the feasibility of using deep, confined aquifers for disposal and, if feasible, identify
potential disposal locations (with the cooperation of the oil and gas industry); (4) evaluate, on a common basis, system and design alternatives for integration of CO -LCB- sub 2 -RCB- capture systems with emerging and advanced technologies for power generation; and prepare a conceptual design, an analysis of barrier issues, and a preliminary cost estimate for pipeline networks necessary to transport a significant portion of the CO -LCB- sub 2 -RCB- to potentially feasible disposal locations.
The research needs that have high priority in establishing the technical, environmental, and economic feasibility of large - scale capture and disposal of CO -LCB- sub 2 -RCB- from
electric power plants are: (1) survey and assess the capacity, cost, and location of
potential depleted gas and oil wells that are suitable CO -LCB- sub 2 -RCB- repositories (with the cooperation of the oil and gas industry); (2) conduct research on the feasibility of ocean disposal, with objectives of determining the cost, residence time, and environmental
effects for different methods of CO -LCB- sub 2 -RCB- injection; (3) perform an in - depth survey of knowledge concerning the feasibility of using deep, confined aquifers for disposal and, if feasible, identify
potential disposal locations (with the cooperation of the oil and gas industry); (4) evaluate, on a common basis, more» system and design alternatives for integration of CO -LCB- sub 2 -RCB- capture systems with emerging and advanced technologies for power generation; and prepare a conceptual design, an analysis of barrier issues, and a preliminary cost estimate for pipeline networks necessary to transport a significant portion of the CO -LCB- sub 2 -RCB- to potentially feasible disposal locations.