Author(s)
International Finance CorporationKeywords
POWER SECTORAVAILABILITY
PRICE
POWER PLANT
COSTS OF ELECTRICITY
POWER STATIONS
RENEWABLE SOURCE
PLANT EFFICIENCY
TURBINE
GRID INTEGRATION
GENERATION CAPACITY
OXYGEN
AUXILIARY EQUIPMENT
WIND
AMOUNT OF POWER
ELECTRICITY SALES
ENERGY DEMAND
TURBINE BLADES
TURBINE GENERATORS
GRID CONNECTION
ENERGY OUTPUT
THERMAL PLANTS
ELECTRICITY GENERATION
GRID CONNECTIONS
ELECTRIC UTILITY
GREENHOUSE GAS
PEAK DEMAND PERIODS
CARBON DIOXIDE
HYDROELECTRIC POWER GENERATION
POWER CAPACITY
OIL
FOSSIL FUELS
ZERO NET PRESENT VALUE
HYDROPOWER
POWER SECTOR PLANNING
AQUATIC HABITATS
APPROACH
COMPRESSED AIR
POWER GRID
POWER GENERATION
ACCESS TO ELECTRICITY
TURBULENCE
ELECTRICITY
CAPACITY FACTOR
DIESEL
SOLAR PROJECTS
FOSSIL
RENEWABLE ENERGY TECHNOLOGIES
GASES
RENEWABLE ENERGY MARKET
POWER LINES
GEOLOGICAL CONDITIONS
TRANSMISSION LINE
EVAPORATION
RENEWABLE ENERGY PROGRAM
ELECTRICITY SUPPLY
POWER
COST OF ELECTRICITY
VERTICAL AXIS
SAND
GREENHOUSE GASES
BATTERY CHARGERS
PEAK POWER
THERMAL POWER
EMPLOYMENT
TAX PAYMENTS
TURBINES
HYDROPOWER PLANT
CARBON EMISSIONS
GENERATOR UNITS
GREENHOUSE GAS EMISSIONS
DEMAND FOR POWER
BALANCE
EMISSIONS
PEAK DEMAND
POWER PLANTS
ENERGY SOURCES
POWER DEMAND
ENERGY STRATEGIES
HYDRO POWER
PRESSURE RISE
RENEWABLE ENERGY
HYDROELECTRIC POWER PLANT
ENVIRONMENTAL IMPACTS
ENERGY PRODUCTION
ELECTRIC POWER GENERATION
TRANSMISSION LINES
ELECTRICITY PRICE
ELECTRICITY PRICES
RENEWABLE SOURCE OF ENERGY
FUELS
ENERGY GENERATION
TURBINE ∗η GENERATOR
ROTATIONAL SPEED
HYDROELECTRIC POWER
GAS PRICE
NATURAL GAS
EMISSION
GENERATION
SOLAR ENERGY
COAL
EMISSIONS REDUCTIONS
ENERGY SUPPLY
HYDRO POWER PLANTS
PEAK LOAD
PEAK POWER GENERATION
FUEL OIL
ACTIVITIES
CLIMATE CHANGE MITIGATION
DRILLING
ENVIRONMENTAL ISSUES
TURBINE COMPONENTS
DISTRIBUTION NETWORK
TRANSMISSION SYSTEM
AIR QUALITY
POLLUTION
POWER SYSTEM
CLIMATIC CONDITIONS
POWER AVAILABILITY
TARIFF
WATER
ENERGY RESOURCES
HYDROPOWER GENERATION
BIRDS
ELECTRIC GENERATOR
RENEWABLE ENERGY SOURCE
INVESTMENT
INVESTMENTS
PRICES
NOZZLES
BIOMASS
CLIMATE CHANGE
GAS
KINETIC ENERGY
UTILITIES
ELECTRICITY PRODUCTION
PETROLEUM
POWER PLANT CONSTRUCTION
RURAL ELECTRIFICATION
ENERGY ALTERNATIVES
ENERGY NEEDS
ENERGY
POLLUTION CONTROL
BATTERIES
VOLTAGE
BURNING FOSSIL FUELS
ELECTRIFICATION
POWER PRODUCTION
THERMAL CAPACITY
ELECTRIC POWER
AIR EMISSIONS
SOURCE OF ENERGY
TURBINE EFFICIENCY
LOAD FACTOR
ENERGY LOSSES
SUSTAINABLE ENERGY
THERMAL POWER PLANTS
OPTIONS
HYDRO PLANT
POWER GENERATORS
ACCESS ROADS
ELECTRICITY DISTRIBUTION
RENEWABLE ENERGY PROJECTS
CAPACITY FACTORS
POLLUTANTS
ENERGY SOURCE
FOSSIL FUEL
POWER STATION
METHANE
PLANT OPERATION
PLANT RELIABILITY
TRANSMISSION FACILITIES
BUFFER ZONES
FUEL
FACILITIES
TURBINE DESIGN
Full record
Show full item recordOnline Access
http://hdl.handle.net/10986/22788Abstract
Worldwide, hydropower is a crucial power supply option for several reasons. First, it is a renewable energy resource that can contribute to sustainable development by generating local, typically inexpensive power. Second, hydropower reduces reliance on imported fuels that carry the risks of price volatility, supply uncertainty and foreign currency requirements. Third, hydro systems can offer multiple co-benefits including water storage for drinking and irrigation, drought-preparedness, flood control protection, aquaculture and recreational opportunities, among others. Finally, hydro can allow more renewables, especially wind and solar, to be added to the system by providing rapid-response power when intermittent sources are off-line, and pumped energy storage when such sources are generating excess powerDate
2015-10-21Type
Publications & ResearchIdentifier
oai:openknowledge.worldbank.org:10986/22788http://hdl.handle.net/10986/22788
Copyright/License
http://creativecommons.org/licenses/by-nc-nd/3.0/igo/Collections
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