Cut Emissions Electricity Enhance Efficiency

Deploy LED Lighting

Office building exterior showing many floors of indoor lit offices

We define the Deploy LED Lighting solution as replacing energy-inefficient light sources with light-emitting diodes (LEDs). Lighting accounts for 15–20% of electricity use in buildings. Using LEDs reduces the electricity that building lighting consumes, and thereby cuts GHG emissions from global electricity generation.

Last updated June 30, 2025

Solution Basics

Adoption Unit

% lamps LED

Effectiveness

tCO₂-eq/unit

7.09×10⁶

Adoption

units

Current 50.58792

Achievable (Low to High)

Climate Impact

Emissions Avoided

GtCO₂-eq/yr

Current 0.36 0.62 0.65

Cost

US$ per tCO₂-eq

-175

Speed of Action

Gradual

Climate Pollutants Mitigated

CO₂, CH₄, N₂O, BC

Additional Benefits

Climate Adaptation

Human Well-being

Environment

Overview

LED technology for lighting indoor and outdoor spaces is more energy-efficient than other lighting sources currently on the market (Zissis et al., 2021). This is because LEDs are solid-state semiconductors that emit light generated through a direct conversion of the flow of electricity (electroluminescence) rather than heating a tungsten filament to make it glow. More of the electrical energy goes to producing light in an LED lamp than in less-efficient alternative lighting technologies such as incandescent light bulbs or compact fluorescent lamps (CFLs) (Koretsky, 2021; Nair & Dhoble, 2021a). This difference offers significant energy-efficiency gains (see Figure 1).

Globally, lighting-related electricity consumption can account for as much as 20% of the total annual electricity used in buildings (Gayral, 2017; Pompei et al., 2020; Pompei et al., 2022). In 2022, the IEA estimated that total electricity consumption for lighting buildings globally was 1,736 TWh (Lane, 2023). Schleich et al. (2014) and others have argued that buildings consume more electricity for lighting when occupants perceive a lighting source as efficient (rebound effect). However, the growing adoption of LED lighting over the years has significantly optimized electricity consumption from building lighting, especially in residential buildings (Lane, 2023).

According to the Intergovernmental Panel on Climate Change (IPCC, 2006), generating electricity from fossil fuels emits CO₂, methane, and nitrous oxide. Replacing inefficient lamps with LEDs cuts these emissions by reducing electricity demand. LEDs often have a power rating of 4–10W, which is 3–10 times lower than alternatives. LEDs also last significantly longer: With a lifespan that can exceed 25,000 hours, they vastly outperform incandescent bulbs (1,000 hours) and CFLs (10,000 hours), as shown in Figure 1. LED’s longevity leads to potential long-term savings due to fewer replacements. The amount of light produced per energy input (luminous efficacy) is up to 10 times greater than alternative lighting sources. This means substantially more lighting for less energy.

Figure 1. A comparison of light sources for building lighting (data from Lane, 2023; Mathias et al., 2023; Nair & Dhoble, 2021b; Xu, 2019).

Light source type	Power rating (watts)	Luminous efficacy (lumens/watt)	Lifespan (hours)
Incandescent	40–100	10–15	1,000
CFL	12–20	60–63	10,000
LED	4–10	110–150	25,000–100,000

The International Energy Agency (IEA) and other international bodies report LED market penetration in terms of percentages of the global lighting market (Lane, 2023). We chose this approach to track the impact of adopting LEDs.

Impact Calculator

Adjust effectiveness and adoption using range sliders to see resulting climate impact potential.

Effectiveness

7.09×10⁶

t CO₂-eq/% lamps LED/yr

Adoption

50.5

% lamps LED

Low

High

50.5

current

Achievable Range

Climate Impact

0.358

Gt CO₂-eq/yr (100-yr)

06 Gt

0.606%

of total global emissions^*

*59.09 Gt CO₂-eq/yr (100-yr basis)

Maps

The Deploy LED Lighting solution can be equally effective at reducing electricity use across global regions because the efficiency gained by replacing other bulbs with LEDs is functionally identical. However, its climate impact will vary with the emissions intensity of each region’s electricity grid. Secondary considerations associated with uptake of LED lighting also can vary with climate and hence geography. In particular, the decrease in heating associated with LED lighting can reduce demands on air conditioning, leading to increased incentive for solution uptake in warmer climates.

Historically, a few countries typically account for the bulk of LEDs purchased. For example, 30% of the 5 billion LEDs sold globally in 2016 were sold in China. In the same period, North America accounted for 15% while Western Europe, Japan, and India represented 11%, 10%, and 8% of the LEDs sold, respectively (Kamat et al., 2020; U.S. DOE, 2016). Essentially, the growing sales of LEDs drove global adoption levels from 17.6% of the building lighting market in 2016 to 50.5% in 2022 (Lane, 2023). However, current adoption still varies considerably around the world. For instance, Lee et al. (2024) reported that LED market penetration in the U.S. was 47.5% in 2020, compared with 43.3% globally in the same period (Lane, 2023). Meanwhile, LED adoption in France was 35% in 2017, and countries in the Middle East such as the United Arab Emirates, Saudi Arabia, and Turkey had over 70% LED adoption that same year; residential buildings in the United Kingdom had 13% LED adoption in 2018, while Japan had 60% LED adoption as of 2019 (Zissis et al., 2021). This demonstrates potential to scale LED adoption in the future, especially in low- and middle-income countries where the bulk of new building occurs (IEA, 2023).

Select data layer

% LED lamps

< 20

20–40

40–60

> 60

No data

Percentage of lamps that are LEDs, circa 2020

The percentage of lamps used to light buildings that are LEDs varies around the world, with limited data available on a per-country basis.

Miah, M. A. R., & Kabir, R. (2023). Energy savings forecast for solid-state lighting in residential and commercial buildings in Bangladesh. IEEE PES 15th Asia-Pacific Power and Energy Engineering Conference (APPEEC), pp. 1-6, doi: 10.1109/APPEEC57400.2023.10561921

U.S. Department of Energy (2024). 2020 U.S. lighting market characterization. https://www.energy.gov/sites/default/files/2024-08/ssl-lmc2020_apr24.pdf

World Furniture Online (2017). The lighting fixtures market in Australia and New Zealand. https://www.worldfurnitureonline.com/report/the-lighting-fixtures-market-in-australia-and-new-zealand/

Zissis, G., Bertoldi, P., & Serrenho, T. (2021). Update on the status of LED-lighting world market since 2018. Publications Office of the European Union. https://publications.jrc.ec.europa.eu/repository/handle/JRC122760

Select data layer

% LED lamps

< 20

20–40

40–60

> 60

No data

Percentage of lamps that are LEDs, circa 2020

The percentage of lamps used to light buildings that are LEDs varies around the world, with limited data available on a per-country basis.

The Details

Current State

Effectiveness

Replacing 1% of the building lighting market with LED lamps avoids approximately 7.09 Mt CO₂‑eq/yr emissions on a 100-yr basis (Table 1) or 7.15 Mt CO₂‑eq/yr on a 20-yr basis.

We estimated this solution’s effectiveness (Table 1) by multiplying the global electricity savings intensity (kWh/%) by an emissions intensity (g/kWh) for each GHG emitted due to electricity generation. Using the IEA (2024)’s energy balances data, we estimated emissions intensities of approximately 529 g/kWh for CO₂, 0.07 g/kWh for methane and 0.01 g/kWh for nitrous oxide. Country-specific data were limited. Therefore, we developed the savings intensity using the IEA’s adoption trend (%/yr) and electricity consumption reduction (kWh/yr) for residential buildings globally (Lane, 2023). We then scaled up the savings intensity to represent all buildings (since LEDs are applicable in all types of buildings), but we could not find global data specifying the energy savings potential of converting the lighting market in nonresidential buildings to LEDs. Notably, artificial lighting’s energy consumption varies across building types (Moadab et al., 2021) and is typically greater in nonresidential buildings (Build Up, 2019). This presents some level of uncertainty, but also suggests that our estimates could be conservative – and that there is potential for even greater savings in nonresidential buildings.

Table 1. Effectiveness at reducing emissions.

Unit: t CO₂‑eq/% lamps LED/yr, 100-yr basis

Estimate

7090000

Cost

Our lifetime initial cost estimate of switching 1% of the global building lighting market to LEDs is approximately US$1.5 billion. Because LEDs use less electricity than alternative lamps, they cost less to operate, resulting in operating costs of –US$1.3 billion/yr (i.e., cost savings). Building owners typically are not paid to use LED lighting; therefore, the revenue is zero. After amortizing the initial cost over 30 years, the net annual cost for this solution is –US$1.2 billion/yr globally. Thus, replacing other bulbs with LEDs saves money despite the initial cost.

We estimated the cost (Table 2) by first identifying initial and operating costs from studies that retrofitted buildings with LEDs, such as Periyannan et al. (2023), Hasan et al. (2024), and Forastiere et al. (2024). We then divided the costs by the impact of the LED retrofit on the amount of electricity consumed by lighting in each study and multiplied this by the global electricity savings intensity (kWh/%) we estimated during the effectiveness analysis. The result was the cost per percent of lamps in buildings converted to LED lighting (US$/% lamps LED).

We estimated the cost per unit climate impact by dividing the annual cost savings per adoption unit by the CO₂‑eq emissions reduced yearly per adoption unit (Table 2).

Table 2. Cost per unit climate impact.

Unit: 2023 US$/t CO₂‑eq, 100-yr basis

median

-175.0

Negative values reflect cost savings.

Learning Curve

As LEDs became more common in building lighting, costs dropped significantly in recent years.

Trends based on LED adoption data (Lane, 2023) and the cost of LED lighting (Pattison et al., 2020) showed a 29.7% drop in cost as LED adoption doubled between 2016 and 2019.

The cost data we used to identify the learning curve for this solution (Table 3) are specific to the United States and limited to pre-2020. More recent LED cost data may show additional cost benefits, but this value may not be applicable for other countries. However, the cost data we analyzed do provide a useful sample of the broader LED cost-reduction trend.

Table 3. Learning rate: drop in cost per doubling of the installed solution base

Units: %

Estimate

29.7

Speed of Action

Speed of action refers to how quickly a climate solution physically affects the atmosphere after it is deployed. This is different from speed of deployment, which is the pace at which solutions are adopted.

At Project Drawdown, we define the speed of action for each climate solution as gradual, emergency brake, or delayed.

Deploy LED Lighting is a GRADUAL climate solution. It has a steady, linear impact on the atmosphere. The cumulative effect over time builds as a straight line.

Adoption

Current Adoption

Lane (2023) found that LED lamps represented 50.5% of the lighting market globally for residential buildings in 2022, but does not provide adoption data specific to nonresidential buildings. Studies that provide global or geographically segmented LED adoption data for all building types are also limited. Therefore, we assume 50.5% to be representative of LED adoption across all buildings globally (Table 4).

Other studies highlight adoption levels across various countries. The data captured in these studies and reports provide context with specific adoption levels from different regions (see Geographic Guidance).

The IEA and U.S. Department of Energy (DOE) report that LEDs are increasingly the preferred choice of homeowners and the general building lighting market. This preference is evident in the growing market share of LED lamps sold and installed annually (Lane, 2023; Lee et al., 2024).

In general, the solution’s current adoption globally is substantial, and we recognize that some countries possess more room for the solution to scale. While adoption barriers vary across regions, many countries are establishing lighting standards to drive LED adoption, especially across Africa [(IEA, 2022; United Nations Industrial Development Organization (UNIDO), 2021].

Table 4. Current (2022) adoption level.

Units: % lamps LED

Estimate

50.5

Adoption Trend

Adoption of LEDs has grown approximately 3.75%/yr over the past two decades.

Lane (2023) found that the proportion of lamps sold annually for building lighting that are LEDs grew from 1.1% in 2010 to 50.5% in 2022 (Figure 2). We estimated the adoption trend (Table 5) by determining the percentage growth between successive years, and calculating the variances.

Data Files

Figure 2. Trend in LED adoption between 2010 and 2022 (adapted from Lane, 2023).

Source: Lane, K. (2023, 11 July 2023). Lighting. International Energy Agency (IEA). Retrieved 13 December 2024 from https://www.iea.org/energy-system/buildings/lighting

Data on the growth of LEDs across regional building lighting markets are limited. Lee et al. (2024)’s analysis of the U.S. lighting market found 46.5% growth 2010–2020, which translates to 4.65% annually. Zissis et al. (2021) reported 26% growth for France for 2017–2020, which averages 8.67% annually.

Table 5. 2010–2022 adoption trend.

Units: % lamps LED market share growth/yr

25th percentile	2.85
mean	4.12
median (50th percentile)	3.75
75th percentile	5.4

Adoption Ceiling

The adoption ceiling (Table 6) is 100%, meaning all lamps in buildings are LEDs. Lane (2023) projects 100% LED market penetration by 2030. If current adoption trends continue, 100% LED adoption is a practical and achievable upper limit. However, countries will need to overcome challenges such as regulatory enforcement, financial, and technology access issues, while preventing the entrance of inferior quality LEDs into their lighting market (IEA, 2022).

Table 6. Adoption ceiling

Units: % lamps LED

Estimate

100

Achievable Adoption

We estimate a low achievable adoption scenario of 87% based on Statista’s projections about LED lighting market penetration by 2030 (Placek, 2023). The values were similar in Zissis et al. (2021).

For the high achievable scenario, we projected 10 years beyond the 2022 adoption level using the mean adoption trend of 4.12%/yr. This translates to a 41% growth on top of the current adoption level of 50.5%, summing up to a 92% LED adoption level (Table 7).

Table 7. Range of achievable adoption levels.

Unit: % lamps LED

Current Adoption	50.5
Achievable – Low	87
Achievable – High	92
Adoption Ceiling	100

Impacts

Climate Impact

We estimated that current adoption cuts about 0.36 Gt CO₂‑eq emissions on a 100-yr basis compared with the previous alternative lighting sources (Table 8). The low achievable adoption scenario of 87% LED lamps could cut emissions 0.62 Gt CO₂‑eq/yr due to reduced electricity consumption, while a high achievable adoption scenario of 92% LED lamps could cut emissions 0.65 Gt CO₂‑eq/yr. If the adoption ceiling of 100% LEDs for lighting buildings is reached, we estimate that 0.71 Gt CO₂‑eq/yr could be avoided (Table 8).

LED lighting could further cut electricity consumption as LED technology continues to improve. However, the technology’s future climate impacts will depend on the emissions of future electricity-generation systems.

Table 8. Climate impact at different levels of adoption.

Unit: Gt CO₂‑eq/yr 100-yr basis

Current Adoption	0.36
Achievable – Low	0.62
Achievable – High	0.65
Adoption Ceiling	0.71

Additional Benefits

Air and Water Quality

The lower electricity demand of LEDs could help reduce emissions from power plants and so improve air quality (Amann et al., 2022). Additionally, LEDs can mitigate small amounts of mercury found in fluorescent lights (Amann et al., 2022). Mercury contamination from discarded bulbs in landfills can leach into surrounding water bodies and accumulate in aquatic life. LEDs also have longer lifespans than fluorescent and incandescent bulbs (Nair & Dhoble, 2021b) which can reduce the amount of discarded bulbs and further mitigate environmental degradation from landfills.

Income and Work

Because LEDs use less electricity than fluorescent and incandescent light bulbs (Khan & Abas, 2011), households and businesses using LED technology can save money on electricity costs. The payback period for the initial investment from lower utility bills is about one year for residential buildings and about two months for commercial buildings (Amann et al., 2022). LED lighting can contribute to savings by minimizing energy demand for cooling, since LEDs emit less heat than fluorescent and incandescent bulbs (Albatayneh et al., 2021; Schratz et al., 2016). However, it could also lead to a greater need for space heating in some regions. LED lights also last longer than alternative lighting technologies, which can lead to lower maintenance costs (Schratz et al., 2016).

Health

Reductions in air pollution due to LED lighting’s lower electricity demand decrease exposures to pollutants such as mercury and fine particulate matter generated from fossil fuel-based power plants, improving the health of nearby communities [Environmental Protection Agency (EPA), 2024]. These pollutants have been linked to increased morbidity from cardiovascular and respiratory disease, asthma, infections, and cancer, (Gasparotto & Martinello, 2021) and to increased risk of mortality (Henneman et al., 2023). Because LEDs do not contain mercury, they can mitigate small health risks associated with mercury exposure when fluorescent light bulbs break (Bose-O’Reilly et al., 2010; Sarigiannis et al., 2012). Switching to LEDs can also enhance a visual environment and improve occupants’ well-being, visual comfort, and overall productivity when lamps with the appropriate lighting quality and correlated color temperature are selected (Fu et al., 2023; Iskra-Golec et al., 2012; Nair & Dhoble, 2021b).

Other

Caveats

Our effectiveness analysis is based on the current state of LED technology. If the adoption ceiling is attained, further improvements to the amount of light that LEDs generate per unit electricity could enhance the solution’s impact through further reductions in electricity use.

The rebound effect – where building occupants use more lighting in response to increased energy-efficiency of lamps – is a well-established concern (Saunders and Tsao, 2012; Schleich et al. 2014). We attempted to address this concern by using IEA data on actual electricity consumption originating from building lighting to determine both its effectiveness and cost implications (Lane, 2023).

We did not fully account for the cost savings that potentially arise from fewer bulb replacements, since LEDs may replace various types of lamps. Because LEDs last significantly longer than all alternative lamp technologies, building owners may require fewer replacements when using LED lamps compared with other lighting sources.

Risks

We found limited data indicating risks with choosing LEDs over other lighting sources. Concerns about eye health raised in the early days of LED adoption (Behar-Cohen et al., 2011) have been allayed by studies that found that LEDs do not pose a greater risk to the eye than comparable lighting sources (Moyano et al. 2020).

LED manufacturing uses metals like gold, indium, and gallium (Gao et al., 2022). This creates environmental risks due to mining (Xiong et al., 2023) and makes LED supply chains susceptible to macroeconomic uncertainties (Lee et al., 2021). With growing adoption of LED lights, there is also the risk of greater electronic waste at the end of the LED’s lifespan. Therefore, recycling is increasingly important (Cenci et al., 2020).

Trade-offs

LED lamp manufacturing creates more emissions than manufacturing other types of lamps. For example, Zhang et al. (2023) compared the manufacturing emissions of a 12.5W LED lamp with a 14W CFL and a 60W incandescent bulb. These light sources provided similar levels of illumination (850–900 lumens). The production of one LED bulb resulted in 9.81 kg CO₂‑eq emissions, while the CFL and incandescent resulted in 2.29 and 0.73 kg CO₂‑eq emissions, respectively. However, LEDs are preferred because their longevity results in fewer LED lamps required to provide the same amount of lighting over time. LEDs can last 25 times longer than incandescent lamps with an identical lumen output (Nair & Dhoble, 2021b; Xu, 2019; Zhang et al., 2023).

Interactions with Other Solutions

Reinforcing

Other lighting sources such as incandescent lamps are known to produce some heat, thus adding to the cooling load. LEDs are more energy-efficient, and therefore could reduce the cooling requirements of a space.

Deploy District Cooling

Competing

Some studies demonstrate an increase in the indoor heating requirements when switching to LED lighting from other lighting sources, such as incandescent lamps, that produce more heat than LEDs. The difference is often small, but worth taking into account when adopting LEDs in a building with previously energy-inefficient lighting.

Evidence Base

The level of consensus about the effectiveness of replacing other lighting sources with LEDs is High.

Using LEDs significantly minimizes the electricity required to light buildings, thereby reducing GHG emissions from electricity generation. Many countries are phasing out other lighting sources to reduce GHG emissions (Lane, 2023).

The IEA reported that global adoption of LEDs drove a nearly 30% reduction in annual electricity consumption for lighting in homes between 2010 and 2022 (Lane, 2023). Hasan et al. (2024) indicated that LEDs could reduce the lighting energy usage of buildings (and their resulting GHG emissions) in Bangladesh by 50%. Periyannan et al. (2023) recorded significant electricity savings after evaluating the impact of retrofitting hotels in Sri Lanka with LEDs. Forastiere et al. (2024)’s analysis of the retail buildings in Italy showed an 11% reduction in energy consumption from replacing other lamps with LEDs. Booysen et al., (2021) also achieved significant energy reduction with lighting retrofits in South African educational buildings.

The results presented in this document summarize findings from six original studies and three public sector/multilateral agency reports, which collectively reflect current evidence both globally and from six countries on four different continents. We recognize this limited geographic scope creates bias, and hope this work inspires research and data sharing on this topic in underrepresented regions.

Take Action

Looking to get involved? Below are some key actions for this solution that can get you started, arranged according to different roles you may play in your professional or personal life.

These actions are meant to be starting points for involvement and are not intended to be prescriptive or necessarily suggest they are the most important or impactful actions to take. We encourage you to explore and get creative!

Lawmakers and Policymakers

Use regulations to phase out and replace energy-inefficient lighting sources with LEDs.
Set regulations that encourage sufficient lighting to limit the overuse of LEDs (or rebound effects).
Require that public lighting use LEDs.
Use financial incentives such as tax breaks, subsidies, and grants to facilitate the transition to LEDs.
Revise building energy-efficiency standards to reflect energy savings of LEDs.
Develop production standards and mandate labeling for LEDs.
Build sufficient inspection capacity for LED manufacturers and penalize noncompliance with standards.
Use energy-efficiency purchase agreements to help support utility companies during the transition to LED lighting.
Invest in research and development that improves the cost and efficiency of LED lighting.
Develop a certification program for LED lighting.
Create exchange programs or buy-back programs for inefficient light bulbs.
Start demonstration projects to promote LED lighting.
Join, support, or create educational programs that raise public awareness about the cost savings and energy-efficiency gains associated with LEDs.

Further information:

Lighting. International Energy Agency (2023)
Energy efficient LED lighting-guide: a guide for business. Sustainable Energy Authority of Ireland (n.d.)
Accelerating the global adoption of energy-efficient lighting. United for Energy Efficiency (2017)
Government relations and public policy job function action guide, Project Drawdown (2022)
Legal job function action guide, Project Drawdown (2022)

Practitioners

Take advantage of or advocate for financial incentives such as tax breaks, subsidies, and grants to facilitate the production of LED lighting.
Help develop circular supply chains in renovating, remanufacturing, reusing, and redistributing materials.
Invest in research and development to improve efficiency and cost of LEDs.
Adhere to, or advocate for, national LED standards.
Develop, produce, and sell LED lighting that imitates incandescent or other familiar lighting.
Consider bundling services with retrofitting companies and collaborating with utility companies to offer rebates or other incentives.
Improve self-service of LEDs by reducing obstacles to installation and ensuring LEDs can be easily replaced.
Help create positive perceptions of LED lighting by showcasing usage, cost savings, and emissions reductions.
Create feedback mechanisms, such as apps that alert users to real-time benefits such as energy and cost savings.
Start demonstration projects to promote LED lighting.
Join, support, or create educational programs that raise public awareness about the cost savings and energy-efficiency gains associated with LEDs.

Further information:

Lighting. International Energy Agency (2023)
Energy efficient LED lighting-guide: a guide for business. Sustainable Energy Authority of Ireland (n.d.)
Accelerating the global adoption of energy-efficient lighting. United for Energy Efficiency (2017)

Business Leaders

Retrofit existing operations for LEDs, replace inefficient bulbs, and purchase only LEDs going forward.
Help develop circular supply chains in renovating, remanufacturing, reusing, and redistributing LED lighting materials.
Take advantage of financial incentives such as tax breaks, subsidies, and grants to facilitate the transition to LED lighting.
Invest in research and development that improves the cost and efficiency of LED lighting.
Join, support, or create educational programs that raise public awareness about the cost savings and energy-efficiency gains associated with LEDs.

Further information:

Lighting. International Energy Agency (2023)
Energy efficient LED lighting-guide: a guide for business. Sustainable Energy Authority of Ireland (n.d.)
Accelerating the global adoption of energy-efficient lighting. United for Energy Efficiency (2017)

Nonprofit Leaders

Retrofit existing operations for LEDs, replace inefficient bulbs, and purchase only LEDs going forward.
Help develop circular supply chains in renovating, remanufacturing, reusing, and redistributing LED lighting materials.
Take advantage of, or advocate for, financial incentives such as tax breaks, subsidies, and grants to facilitate the transition to LED lighting.
Advocate for regulations to phase out and replace energy-inefficient lighting sources with LEDs.
Advocate for production standards and labeling for LEDs.
Call for regulations that encourage sufficient lighting to limit the overuse of LEDs (or rebound effects).
Start demonstration projects to promote LED lighting.
Help develop, support, or administer a certification program for LED lighting.
Create national catalogs of LED manufacturers, suppliers, and retailers.
Join, support, or create educational programs that raise public awareness about the cost savings and energy-efficiency gains associated with LEDs.

Further information:

Lighting. International Energy Agency (2023)
Energy efficient LED lighting-guide: a guide for business. Sustainable Energy Authority of Ireland (n.d.)
Accelerating the global adoption of energy-efficient lighting. United for Energy Efficiency (2017)

Investors

Retrofit existing operations for LEDs, replace inefficient bulbs, and purchase only LEDs going forward.
Take advantage of financial incentives such as tax breaks, subsidies, and grants to facilitate the transition to LED lighting.
Invest in LED manufacturers, supply chains, and supportive industries.
Support research and development to improve the efficiency and cost of LEDs.
Invest in LED companies.
Fund companies that provide retrofitting services (energy service companies).
Invest in businesses dedicated to advancing LED use.
Ensure portfolio companies do not produce or support non-LED lighting supply chains.
Join, support, or create educational programs that raise public awareness about the cost savings and energy-efficiency gains associated with LEDs.

Further information:

Lighting. International Energy Agency (2023)
Energy efficient LED lighting-guide: a guide for business. Sustainable Energy Authority of Ireland (n.d.)
Accelerating the global adoption of energy-efficient lighting. United for Energy Efficiency (2017)

Philanthropists and International Aid Agencies

Retrofit existing operations for LEDs, replace inefficient bulbs, and purchase only LEDs going forward.
Take advantage of financial incentives such as tax breaks, subsidies, and grants to facilitate the transition to LED lighting.
Provide financing such as low-interest loans, grants, and micro-grants to help accelerate LED adoption.
Fund companies that provide retrofitting services (energy service companies).
Advocate for regulations to phase out energy-inefficient lighting sources and replace them with LEDs.
Call for regulations that encourage sufficient lighting to limit the overuse of LEDs (or rebound effects).
Start demonstration projects to promote LED lighting.
Help develop, support, or administer a certification program for LED lighting.
Create national catalogs of LED manufacturers, suppliers, and retailers.
Join, support, or create educational programs that raise public awareness about the cost savings and energy-efficiency gains associated with LEDs.

Further information:

Lighting. International Energy Agency (2023)
Energy efficient LED lighting-guide: a guide for business. Sustainable Energy Authority of Ireland (n.d.)
Accelerating the global adoption of energy-efficient lighting. United for Energy Efficiency (2017)

Thought Leaders

Retrofit buildings for LED lighting, replace inefficient bulbs, and purchase only LEDs going forward.
Help create positive perceptions of LED lighting by highlighting your personal usage, cost and energy savings, and emissions reductions.
Help develop circular supply chains in renovating, remanufacturing, reusing, and redistributing materials.
Take advantage of, or advocate for, financial incentives such as tax breaks, subsidies, and grants to facilitate the transition to LED lighting.
Advocate for regulations to phase out energy-inefficient lighting sources and replace them with LEDs.
Advocate for LED standards.
Advocate for regulations that encourage sufficient lighting and guard against overuse of LEDs (or rebound effects).
Start demonstration projects to promote LED lighting.
Help develop, support, or administer a certification program for LED lighting.
Create national catalogs of LED manufacturers, suppliers, and retailers.
Join, support, or create educational programs that raise public awareness about the cost savings and energy-efficiency gains associated with LEDs.

Further information:

Lighting. International Energy Agency (2023)
Energy efficient LED lighting-guide: a guide for business. Sustainable Energy Authority of Ireland (n.d.)
Accelerating the global adoption of energy-efficient lighting. United for Energy Efficiency (2017)

Technologists and Researchers

Develop circular supply chains in renovating, remanufacturing, reusing, and redistributing materials.
Improve the efficiency and cost of LEDs.
Improve LED lighting to imitate familiar lighting, offer customers settings, and augment color rendering.
Improve self-service of LEDs by reducing obstacles to installation and ensuring LEDs can be replaced individually.
Help develop standards for LEDs.
Create feedback mechanisms, such as apps that alert users to real-time benefits such as energy and cost savings.

Further information:

Lighting. International Energy Agency (2023)
Energy efficient LED lighting-guide: a guide for business. Sustainable Energy Authority of Ireland (n.d.)
Accelerating the global adoption of energy-efficient lighting. United for Energy Efficiency (2017)

Communities, Households, and Individuals

Retrofit for LEDs, replace inefficient bulbs, and purchase only LEDs going forward.
Help create positive perceptions of LED lighting by highlighting your personal usage, cost and energy savings, and emissions reductions.
Help develop circular supply chains in renovating, remanufacturing, reusing, and redistributing materials.
Take advantage of or advocate for financial incentives such as tax breaks, subsidies, and grants to facilitate the transition to LED lighting.
Advocate for regulations to phase out and replace energy-inefficient lighting sources with LEDs.
Advocate for LED standards.
Advocate for regulations that encourage sufficient lighting to limit the overuse of LEDs (or rebound effects).
Join, support, or create educational programs that raise public awareness about the cost savings and energy-efficiency gains associated with LEDs.

Further information:

Lighting. International Energy Agency (2023)
Energy efficient LED lighting-guide: a guide for business. Sustainable Energy Authority of Ireland (n.d.)
Accelerating the global adoption of energy-efficient lighting. United for Energy Efficiency (2017)

“Take Action” Sources

Study on policy and measures, standards and certification system of LED lighting industry in Malaysia. Ding et al. (2020)
Study on policy and standard system of LED lighting industry in EU. Ding et al. (2020)
LEDs for lighting: basic physics and prospects for energy savings. Gayral (2017)
Lighting. International Energy Agency (2023)
Phasing out an embedded technology: insights from banning the incandescent light bulb in Europe. Koretsky (2021)
Role of street-level policy entrepreneurs in sustainability transition: evidence from India’s transition to LED lighting. Sharma (2024)
Policy performance of green lighting industry in China: a DID analysis from the perspective of energy conservation and emission reduction. Wang et al. (2020)

References

Albatayneh, A., Juaidi, A., Abdallah, R., & Manzano-Agugliaro, F. (2021). Influence of the advancement in the LED lighting technologies on the optimum windows-to-wall ratio of Jordanians residential buildings. Energies, 14(17), 5446. https://www.mdpi.com/1996-1073/14/17/5446

Amann, J. T., Fadie, B., Mauer, J., Swaroop, K., & Tolentino, C. (2022). Farewell to fluorescent lighting: How a phaseout can cut mercury pollution, protect the climate, and save money. https://www.aceee.org/research-report/b2202

Behar-Cohen, F., Martinsons, C., Viénot, F., Zissis, G., Barlier-Salsi, A., Cesarini, J. P.,…Attia, D. (2011). Light-emitting diodes (LED) for domestic lighting: Any risks for the eye? Progress in Retinal and Eye Research, 30(4), 239–257. https://doi.org/10.1016/j.preteyeres.2011.04.002

Booysen, M. J., Samuels, J. A., & Grobbelaar, S. S. (2021). LED there be light: The impact of replacing lights at schools in South Africa. Energy and Buildings, 235, 110736. https://doi.org/10.1016/j.enbuild.2021.110736

Bose-O'Reilly, S., McCarty, K. M., Steckling, N., & Lettmeier, B. (2010). Mercury exposure and children's health. Current Problems in Pediatric and Adolescent Health Care, 40(8), 186–215. https://doi.org/10.1016/j.cppeds.2010.07.002

Build Up. (2019). Overview_Decarbonising the non-residential building stock. European Commission. Retrieved 05 March 2025 from https://build-up.ec.europa.eu/en/resources-and-tools/articles/overview-decarbonising-non-residential-building-stock

Cenci, M. P., Dal Berto, F. C., Schneider, E. L., & Veit, H. M. (2020). Assessment of LED lamps components and materials for a recycling perspective. Waste Management, 107, 285-293. https://doi.org/10.1016/j.wasman.2020.04.028

Environmental Protection Agency (EPA). (2024). Power sector programs - progress report. https://www.epa.gov/power-sector/progress-report

Forastiere, S., Piselli, C., Silei, A., Sciurpi, F., Pisello, A. L., Cotana, F., & Balocco, C. (2024). Energy efficiency and sustainability in food retail buildings: Introducing a novel assessment framework. Energies, 17(19), 4882. https://www.mdpi.com/1996-1073/17/19/4882

Fu, X., Feng, D., Jiang, X., & Wu, T. (2023). The effect of correlated color temperature and illumination level of LED lighting on visual comfort during sustained attention activities. Sustainability, 15(4), 3826. https://www.mdpi.com/2071-1050/15/4/3826

Gao, W., Sun, Z., Wu, Y., Song, J., Tao, T., Chen, F.,…Cao, H. (2022). Criticality assessment of metal resources for light-emitting diode (LED) production – a case study in China. Cleaner Engineering and Technology, 6, 100380. https://doi.org/10.1016/j.clet.2021.100380

Gasparotto, J., & Da Boit Martinello, K. (2021). Coal as an energy source and its impacts on human health. Energy Geoscience, 2(2), 113–120. https://doi.org/10.1016/j.engeos.2020.07.003

Gayral, B. (2017). LEDs for lighting: Basic physics and prospects for energy savings. Comptes Rendus Physique, 18(7), 453–461. https://doi.org/10.1016/j.crhy.2017.09.001

Gromada, A., & Trębska, P. (2024). Energy efficiency—case study for households in poland. Energies, 17(18), 4592. https://www.mdpi.com/1996-1073/17/18/4592

Hasan, M. M., Moznuzzaman, M., Shaha, A., & Khan, I. (2024). Enhancing energy efficiency in Bangladesh's readymade garment sector: The untapped potential of LED lighting retrofits. International Journal of Energy Sector Management, ahead-of-print(ahead-of-print). https://doi.org/10.1108/IJESM-05-2024-0009

Henneman, L., Choirat, C., Dedoussi, I., Dominici, F., Roberts, J., & Zigler, C. (2023). Mortality risk from United States coal electricity generation. 382(6673), 941–946. https://doi.org/doi:10.1126/science.adf4915

Intergovernmental Panel on Climate Change (IPCC). (2006). 2022 IPCC guidelines for national greenhouse gas inventories volume 3: Energy; Chapter 2: Stationary combustion. https://www.ipcc-nggip.iges.or.jp/public/2006gl/pdf/2_Volume2/V2_2_Ch2_Stationary_Combustion.pdf

International Energy Agency (IEA). (2022). Targeting 100% LED lighting sales by 2025. https://www.iea.org/reports/targeting-100-led-lighting-sales-by-2025

International Energy Agency (IEA). (2023). Global floor area and buildings energy intensity in the net zero scenario, 2010-2030. Retrieved 06 March 2025 from https://www.iea.org/data-and-statistics/charts/global-floor-area-and-buildings-energy-intensity-in-the-net-zero-scenario-2010-2030

International Energy Agency (IEA). (2024). World energy balances. IEA. https://www.iea.org/data-and-statistics/data-product/world-energy-balances

Iskra-Golec, I., Wazna, A., & Smith, L. (2012). Effects of blue-enriched light on the daily course of mood, sleepiness and light perception: A field experiment. 44(4), 506-513. https://doi.org/10.1177/1477153512447528

Kamat, A. S., Khosla, R., & Narayanamurti, V. (2020). Illuminating homes with LEDs in india: Rapid market creation towards low-carbon technology transition in a developing country. Energy Research & Social Science, 66, 101488. https://doi.org/10.1016/j.erss.2020.101488

Khan, N., & Abas, N. (2011). Comparative study of energy saving light sources. Renewable and Sustainable Energy Reviews, 15(1), 296–309. https://doi.org/10.1016/j.rser.2010.07.072

Koretsky, Z. (2021). Phasing out an embedded technology: Insights from banning the incandescent light bulb in europe. Energy Research & Social Science, 82, 102310. https://doi.org/10.1016/j.erss.2021.102310

Lane, K. (2023, 11 July 2023). Lighting. International Energy Agency (IEA). Retrieved 13 December 2024 from https://www.iea.org/energy-system/buildings/lighting

Lee, K., Donnelly, S., & Phillips, G. (2024). 2020 U.S. Lighting market characterization. https://www.osti.gov/biblio/2371534

Lee, K., Nubbe, V., Rego, B., Hansen, M., & Pattison, M. (2021). 2020 LED manufacturing supply chain. U. S. DOE. https://www.energy.gov/sites/default/files/2021-05/ssl-2020-led-mfg-supply-chain-mar21.pdf

Mathias, J. A., Juenger, K. M., & Horton, J. J. (2023). Advances in the energy efficiency of residential appliances in the US: A review. Energy Efficiency, 16(5), 34. https://doi.org/10.1007/s12053-023-10114-8

Moadab, N. H., Olsson, T., Fischl, G., & Aries, M. (2021). Smart versus conventional lighting in apartments - electric lighting energy consumption simulation for three different households. Energy and Buildings, 244, 111009. https://doi.org/10.1016/j.enbuild.2021.111009

Moyano, D. B., Moyano, S. B., López, M. G., Aznal, A. S., & Lezcano, R. A. G. (2020). Nominal risk analysis of the blue light from LED luminaires in indoor lighting design. Optik, 223, 165599. https://doi.org/10.1016/j.ijleo.2020.165599

Nair, G. B., & Dhoble, S. J. (2021a). 2 - fundamentals of LEDs. In G. B. Nair & S. J. Dhoble (Eds.), The fundamentals and applications of light-emitting diodes (pp. 35–57). Woodhead Publishing. https://doi.org/10.1016/B978-0-12-819605-2.00002-1

Nair, G. B., & Dhoble, S. J. (2021b). 6 - general lighting. In G. B. Nair & S. J. Dhoble (Eds.), The fundamentals and applications of light-emitting diodes (pp. 155–176). Woodhead Publishing. https://doi.org/10.1016/B978-0-12-819605-2.00006-9

Pattison, M., Hansen, M., Bardsley, N., Elliott, C., Lee, K., Pattison, L., & Tsao, J. (2020). 2019 lighting R&D opportunities. https://www.osti.gov/biblio/1618035

Periyannan, E., Ramachandra, T., & Geekiyanage, D. (2023). Assessment of costs and benefits of green retrofit technologies: Case study of hotel buildings in Sri Lanka. Journal of Building Engineering, 78, 107631. https://doi.org/10.1016/j.jobe.2023.107631

Placek, M. (2023). LED lighting in the United States - statistics & facts. Statista. Retrieved 09 February 2025 from https://www.statista.com/topics/1144/led-lighting-in-the-us/#topicOverview

Pompei, L., Blaso, L., Fumagalli, S., & Bisegna, F. (2022). The impact of key parameters on the energy requirements for artificial lighting in Italian buildings based on standard en 15193-1:2017. Energy and Buildings, 263, 112025. https://doi.org/10.1016/j.enbuild.2022.112025

Pompei, L., Mattoni, B., Bisegna, F., Blaso, L., & Fumagalli, S. (2020, 9–12 June 2020). Evaluation of the energy consumption of an educational building, based on the uni en 15193–1:2017, varying different lighting control systems. 2020 IEEE International Conference on Environment and Electrical Engineering and 2020 IEEE Industrial and Commercial Power Systems Europe (EEEIC / I&CPS Europe)

Sarigiannis, D. A., Karakitsios, S. P., Antonakopoulou, M. P., & Gotti, A. (2012). Exposure analysis of accidental release of mercury from compact fluorescent lamps (CFLs). Science of The Total Environment, 435–436, 306–315. https://doi.org/10.1016/j.scitotenv.2012.07.026

Saunders, H. D., & Tsao, J. Y. (2012). Rebound effects for lighting. Energy Policy, 49, 477-478. https://doi.org/10.1016/j.enpol.2012.06.050

Schleich, J., Mills, B., & Dütschke, E. (2014). A brighter future? Quantifying the rebound effect in energy efficient lighting. Energy Policy, 72, 35–42. https://doi.org/10.1016/j.enpol.2014.04.028

Schratz, M., Gupta, C., Struhs, T. J., & Gray, K. (2016). A new way to see the light: Improving light quality with cost-effective led technology. IEEE Industry Applications Magazine, 22(4), 55–62. https://doi.org/10.1109/MIAS.2015.2459089

United Nations Industrial Development Organization (UNIDO). (2021). SADC member states welcome the introduction of new efficient lighting standards. UNIDO. Retrieved 05 March 2025 from https://www.unido.org/news/sadc-member-states-welcome-introduction-new-efficient-lighting-standards

U.S. Department of Energy (DOE). (2016). Solid-state lighting R&D plan. https://www.energy.gov/sites/prod/files/2016/06/f32/ssl_rd-plan_%20jun2016_2.pdf

Xiong, Y., Guo, H., Nor, D. D. M. M., Song, A., & Dai, L. (2023). Mineral resources depletion, environmental degradation, and exploitation of natural resources: Covid-19 aftereffects. Resources Policy, 85, 103907. https://doi.org/10.1016/j.resourpol.2023.103907

Xu, Y. (2019). Chapter 2.1 - nature and source of light for plant factory. In M. Anpo, H. Fukuda, & T. Wada (Eds.), Plant factory using artificial light (pp. 47–69). Elsevier. https://doi.org/10.1016/B978-0-12-813973-8.00002-6

Zhang, H., Cai, J., & Braun, J. E. (2023). A whole building life-cycle assessment methodology and its application for carbon footprint analysis of U.S. Commercial buildings. Journal of Building Performance Simulation, 16(1), 38–56. https://doi.org/10.1080/19401493.2022.2107071

Zissis, G., Bertoldi, P., & Serrenho, T. (2021). Update on the status of LED-lighting world market since 2018. Publications Office of the European Union. https://publications.jrc.ec.europa.eu/repository/handle/JRC122760

Credits

Lead Fellow

Henry Igugu

Contributors

Ruthie Burrows
James Gerber
Daniel Jasper
Alex Sweeney

Internal Reviewers

Aiyana Bodi
Hannah Henkin
Megan Matthews
Ted Otte
Amanda Smith
Tina Swanson

Methods and Supporting Data

Comments / Questions

Greenhouse gas quantity expressed relative to CO₂ with the same warming impact over 100 years, calculated by multiplying emissions by the 100-yr GWP for the emitted gases.
Greenhouse gas quantity expressed relative to CO₂ with the same warming impact over 20 years, calculated by multiplying emissions by the 20-yr GWP for the emitted gases.
Reducing greenhouse gas concentrations in the atmosphere by preventing or reducing emissions.
The process of increasing the acidity of water or soil due to increased levels of certain air pollutants.
Benefits of climate solutions that extend beyond their ability to reduce emissions or store carbon (e.g., benefits to public health, water quality, biodiversity, advancing human rights).
The extent to which emissions reduction or carbon removal is above and beyond what would have occurred without implementing a particular action or solution.
An upper limit on solution adoption based on physical or technical constraints, not including economic or policy barriers. This level is unlikely to be reached and will not be exceeded.
The quantity and metric to measure implementation for a particular solution that is used as the reference unit for calculations within that solution.
Farming practices that work to create socially and ecologically sustainable food production.
Addition of trees and shrubs to crop or animal farming systems.
Spread out the cost of an asset over its useful lifetime.
A crop that live one year or less from planting to harvest; also called annual.
black carbon
Made from material of biological origin, such as plants, animals, or other organisms.
A renewable energy source generated from organic matter from plants and/or algae.
An energy source composed primarily of methane and CO₂ that is produced by microorganisms when organic matter decomposes in the absence of oxygen.
Carbon stored in biological matter, including soil, plants, fungi, and plant products (e.g., wood, paper, biofuels). This carbon is sequestered from the atmosphere but can be released through decomposition or burning.
Living or dead renewable matter from plants or animals, not including organic material transformed into fossil fuels. Peat, in early decay stages, is partially renewable biomass.
A type of carbon sequestration that captures carbon from CO₂ via photosynthesis and stores it in soils, sediments, and biomass, distinct from sequestration through chemical or industrial pathways.
A climate pollutant, also called soot, produced from incomplete combustion of organic matter, either naturally (wildfires) or from human activities (biomass or fossil fuel burning).
High-latitude (>50°N or >50°S) climate regions characterized by short growing seasons and cold temperatures.
The components of a building that physically separate the indoors from the outdoor environment.
Businesses involved in the sale and/or distribution of solution-related equipment and technology, and businesses that want to support adoption of the solution.
A chemical reaction involving heating a solid to a high temperature: to make cement clinker, limestone is calcined into lime in a process that requires high heat and produces CO₂.
A four-wheeled passenger vehicle.
Technologies that collect CO₂ before it enters the atmosphere, preventing emissions at their source. Collected CO₂ can be used onsite or in new products, or stored long term to prevent release.
A greenhouse gas that is naturally found in the atmosphere. Its atmospheric concentration has been increasing due to human activities, leading to warming and climate impacts.
Total GHG emissions resulting from a particular action, material, technology, or sector.
Amount of GHG emissions released per activity or unit of production.
A marketplace where carbon credits are purchased and sold. One carbon credit represents activities that avoid, reduce, or remove one metric ton of GHG emissions.
A colorless, odorless gas released during the incomplete combustion of fuels containing carbon. Carbon monoxide can harm health and be fatal at high concentrations.
Activities or technologies that pull CO₂ out of the atmosphere, including enhancing natural carbon sinks and deploying engineered sinks.
Long-term storage of carbon in soils, sediment, biomass, oceans, and geologic formations after removal of CO₂ from the atmosphere or CO₂ capture from industrial and power generation processes.
carbon capture and storage
carbon capture, utilization, and storage
A binding ingredient in concrete responsible for most of concrete’s life-cycle emissions. Cement is made primarily of clinker mixed with other mineral components.
methane
Gases or particles that have a planet-warming effect when released to the atmosphere. Some climate pollutants also cause other forms of environmental damage.
A binding ingredient in cement responsible for most of the life-cycle emissions from cement and concrete production.
carbon monoxide
Neighbors, volunteer organizations, hobbyists and interest groups, online communities, early adopters, individuals sharing a home, and private citizens seeking to support the solution.
A solution that potentially lowers the benefit of another solution through reduced effectiveness, higher costs, reduced or delayed adoption, or diminished global climate impact.
A farming system that combines reduced tillage, cover crops, and crop rotations.
carbon dioxide
A measure standardizing the warming effects of greenhouse gases relative to CO₂. CO₂-eq is calculated as quantity (metric tons) of a particular gas multiplied by its GWP.
carbon dioxide equivalent
The process of cutting greenhouse gas emissions (primarily CO₂) from a particular sector or activity.
A solution that works slower than gradual solutions and is expected to take longer to reach its full potential.
Microbial conversion of nitrate into inert nitrogen gas under low-oxygen conditions, which produces the greenhouse gas nitrous oxide as an intermediate compound.
Greenhouse gas emissions produced as a direct result of the use of a technology or practice.
Ability of a solution to reduce emissions or remove carbon, expressed in CO₂-eq per installed adoption unit. Effectiveness is quantified per year when the adoption unit is cumulative over time.
Greenhouse gas emissions accrued over the lifetime of a material or product, including as it is produced, transported, used, and disposed of.
Solutions that work faster than gradual solutions, front-loading their impact in the near term.
Methane produced by microbes in the digestive tracts of ruminant livestock, such as cattle, sheep and goats.
environmental, social, and governance
exchange-traded fund
A process triggered by an overabundance of nutrients in water, particularly nitrogen and phosphorus, that stimulates excessive plant and algae growth and can harm aquatic organisms.
The scientific literature that supports our assessment of a solution's effectiveness.
A group of human-made molecules that contain fluorine atoms. They are potent greenhouse gases with GWPs that can be hundreds to thousands times higher than CO₂.
food loss and waste
Food discarded during pre-consumer supply chain stages, including production, harvest, and processing.
Food discarded at the retail and consumer stages of the supply chain.
Combustible materials found in Earth's crust that can be burned for energy, including oil, natural gas, and coal. They are formed from decayed organisms through prehistoric geological processes.
greenhouse gas
gigajoule or billion joules
The glass layers or panes in a window.
A measure of how effectively a gas traps heat in the atmosphere relative to CO₂. GWP converts greenhouse gases into CO₂-eq emissions based on their 20- or 100-year impacts.
A solution that has a steady impact so that the cumulative effect over time builds as a straight line. Most climate solutions fall into this category.
A gas that traps heat in the atmosphere, contributing to climate change.
metric gigatons or billion metric tons
global warming potential
hectare
household air pollution
Number of years a person is expected to live without disability or other limitations that restrict basic functioning and activity.
A unit of land area comprising 10,000 square meters, roughly equal to 2.5 acres.
hydrofluorocarbon
hydrofluoroolefin
Particles and gases released from use of polluting fuels and technologies such as biomass cookstoves that cause poor air quality in and around the home.
Organic compounds that contain hydrogen and carbon.
Human-made F-gases that contain hydrogen, fluorine, and carbon. They typically have short atmospheric lifetimes and GWPs hundreds or thousands times higher than CO₂.
Human-made F-gases that contain hydrogen, fluorine, and carbon, with at least one double bond. They have low GWPs and can be climate-friendly alternatives to HFC refrigerants.
internal combustion engine
Greenhouse gas emissions produced as a result of a technology or practice but not directly from its use.
Device used to power vehicles by the intake, compression, combustion, and exhaust of fuel that drives moving parts.
The annual discount rate that balances net cash flows for a project over time. Also called IRR, internal rate of return is used to estimate profitability of potential investments.
Individuals or institutions willing to lend money in search of a return on their investment.
internal rate of return
A measure of energy
International agreement adopted in 2016 to phase down the use of high-GWP HFC F-gases over the time frame 2019–2047.
A measure of energy equivalent to the energy delivered by 1,000 watts of power over one hour.
kiloton or one thousand metric tons
kilowatt-hour
A land-holding system, e.g. ownership, leasing, or renting. Secure land tenure means farmers or other land users will maintain access to and use of the land in future years.
Gases, mainly methane and CO₂, created by the decomposition of organic matter in the absence of oxygen.
leak detection and repair
Regular monitoring for fugitive methane leaks throughout oil and gas, coal, and landfill sector infrastructure and the modification or replacement of leaking equipment.
Relocation of emissions-causing activities outside of a mitigation project area rather than a true reduction in emissions.
The rate at which solution costs decrease as adoption increases, based on production efficiencies, technological improvements, or other factors.
Percent decrease in costs per doubling of adoption.
landfill gas
Greenhouse gas emissions from the sourcing, production, use, and disposal of a technology or practice.
low- and middle-income countries
liquefied petroleum gas
A measure of the amount of light produced by a light source per energy input.
square meter kelvins per watt (a measure of thermal resistance, also called R-value)
marginal abatement cost curve
Livestock grazing practices that strategically manage livestock density, grazing intensity, and timing. Also called improved grazing, these practices have environmental, soil health, and climate benefits, including enhanced soil carbon sequestration.
A tool to measure and compare the financial cost and abatement benefit of individual actions based on the initial and operating costs, revenue, and emission reduction potential.
A greenhouse gas with a short lifetime and high GWP that can be produced through a variety of mechanisms including the breakdown of organic matter.
A measure of mass equivalent to 1,000 kilograms (~2,200 lbs).
million hectares
Soils mostly composed of inorganic materials formed through the breakdown of rocks. Most soils are mineral soils, and they generally have less than 20% organic matter by weight.
A localized electricity system that independently generates and distributes power. Typically serving limited geographic areas, mini-grids can operate in isolation or interconnected with the main grid.
Reducing the concentration of greenhouse gases in the atmosphere by cutting emissions or removing CO₂.
Percent of trips made by different passenger and freight transportation modes.
megaton or million metric tons
A commitment from a country to reduce national emissions and/or sequester carbon in alignment with global climate goals under the Paris Agreement, including plans for adapting to climate impacts.
A gaseous form of hydrocarbons consisting mainly of methane.
Chemicals found in nature that are used for cooling and heating, such as CO₂, ammonia, and some hydrocarbons. They have low GWPs and are ozone friendly, making them climate-friendly refrigerants.
Microbial conversion of ammonia or ammonium to nitrite and then to nitrate under aerobic conditions.
A group of air pollutant molecules composed of nitrogen and oxygen, including NO and NO₂.
A greenhouse gas produced during fossil fuel combustion and agricultural and industrial processes. N₂O is hundreds of times more potent than CO₂ at trapping atmospheric heat, and it depletes stratospheric ozone.
Social welfare organizations, civic leagues, social clubs, labor organizations, business associations, and other not-for-profit organizations.
A material or energy source that relies on resources that are finite or not naturally replenished at the rate of consumption, including fossil fuels like coal, oil, and natural gas.
nitrogen oxides
nitrous oxide
The process of increasing the acidity of seawater, primarily caused by absorption of CO₂ from the atmosphere.
An agreement between a seller who will produce future goods and a purchaser who commits to buying them, often used as project financing for producers prior to manufacturing.
Productive use of wet or rewetted peatlands that does not disturb the peat layer, such as for hunting, gathering, and growing wetland-adapted crops for food, fiber, and energy.
A measure of transporting one passenger over a distance of one kilometer.
The longevity of any greenhouse gas emission reductions or removals. Solution impacts are considered permanent if the risk of reversing the positive climate impacts is low within 100 years.
A mixture of hydrocarbons, small amounts of other organic compounds, and trace amounts of metals used to produce products such as fuels or plastics.
Private, national, or multilateral organizations dedicated to providing aid through in-kind or financial donations.
An atmospheric reaction among sunlight, VOCs, and nitrogen oxide that leads to ground-level ozone formation. Ground-level ozone, a component of smog, harms human health and the environment.
passenger kilometer
particulate matter
Particulate matter 2.5 micrometers or less in diameter that can harm human health when inhaled.
Elected officials and their staff, bureaucrats, civil servants, regulators, attorneys, and government affairs professionals.
System in a vehicle that generates power and delivers it to the wheels. It typically includes an engine and/or motor, transmission, driveshaft, and differential.
People who most directly interface with a solution and/or determine whether the solution is used and/or available.
The process of converting inorganic matter, including carbon dioxide, into organic matter (biomass), primarily by photosynthetic organisms such as plants and algae.
Defined by the International Union for the Conservation of Nature as: "A clearly defined geographical space, recognised, dedicated and managed, through legal or other effective means, to achieve the long-term conservation of nature with associated ecosystem services and cultural values". References to PAs here also include other effective area-based conservation measures defined by the IUCN.
Very large or small numbers are formatted in scientific notation. A positive exponent multiplies the number by powers of ten; a negative exponent divides the number by powers of ten.
Small-scale family farmers and other food producers, often with limited resources, usually in the tropics. The average size of a smallholder farm is two hectares (about five acres).
soil organic carbon
Carbon stored in soils, including both organic (from decomposing plants and microbes) and inorganic (from carbonate-containing minerals).
Carbon stored in soils in organic forms (from decomposing plants and microbes). Soil organic carbon makes up roughly half of soil organic matter by weight.
Biologically derived matter in soils, including living, dead, and decayed plant and microbial tissues. Soil organic matter is roughly half carbon on a dry-weight basis.
soil organic matter
sulfur oxides
sulfur dioxide
The rate at which a climate solution physically affects the atmosphere after being deployed. At Project Drawdown, we use three categories: emergency brake (fastest impact), gradual, or delayed (slowest impact).
Climate regions between latitudes 23.4° to 35° above and below the equator characterized by warm summers and mild winters.
A polluting gas produced primarily from burning fossil fuels and industrial processes that directly harms the environment and human health.
A group of gases containing sulfur and oxygen that predominantly come from burning fossil fuels. They contribute to air pollution, acid rain, and respiratory health issues.
Processes, people, and resources involved in producing and delivering a product from supplier to end customer, including material acquisition.
metric tons
Technology developers, including founders, designers, inventors, R&D staff, and creators seeking to overcome technical or practical challenges.
Climate regions between 35° to 50° above and below the equator characterized by moderate mean annual temperatures and distinct seasons, with warm summers and cold winters.
A measure of how well a material prevents heat flow, often called R-value or RSI-value for insulation. A higher R-value means better thermal performance.
Individuals with an established audience for their work, including public figures, experts, journalists, and educators.
Low-latitude (23.4°S to 23.4°N) climate regions near the Equator characterized by year-round high temperatures and distinct wet and dry seasons.
United Nations
Self-propelled machine for transporting passengers or freight on roads.
A measure of one vehicle traveling a distance of one kilometer.
vehicle kilometer
volatile organic compound
Gases made of organic, carbon-based molecules that are readily released into the air from other solid or liquid materials. Some VOCs are greenhouse gases or can harm human health.
watt
A measure of power equal to one joule per second.
A subset of forest ecosystems that may have sparser canopy cover, smaller-stature trees, and/or trees characterized by basal branching rather than a single main stem.
year

Deploy LED Lighting

Share this solution:

Solution Basics

Climate Impact

Additional Benefits

Overview

Impact Calculator

Effectiveness

Adoption

Climate Impact

Maps

Percentage of lamps that are LEDs, circa 2020

Percentage of lamps that are LEDs, circa 2020

The Details

Current State

Adoption

Impacts

Air and Water Quality

Income and Work

Health

Other

Reinforcing

Competing

Take Action

Further information:

Further information:

Further information:

Further information:

Further information:

Further information:

Further information:

Further information:

Further information:

Lead Fellow

Contributors

Internal Reviewers

Sign Up For Our Newsletter