Mapped: How every part of the world has warmed – and could continue to warm

Rosamund Pearce

Climate change is often communicated by looking at the global average temperature. But a global average might not mean much to the average person. How the climate is likely to change specifically where people live is, in most cases, a much more important consideration.

Carbon Brief has combined observed temperature changes with future climate model projections to show how the climate has changed up to present day, but also how it might change in the future for every different part of the world.

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Glossary

RCP2.6: The RCPs (Representative Concentration Pathways) are scenarios of future concentrations of greenhouse gases and other forcings. RCP2.6 (also sometimes referred to as “RCP3-PD”) is a “peak and decline” scenario where stringent mitigation and carbon dioxide removal technologies mean atmospheric CO2 concentration peaks and then falls during this century. By 2100, CO2 levels increase to around 420ppm – around 20ppm above current levels – equivalent to 475ppm once other forcings are included (in CO2e). By 2100, global temperatures are likely to rise by 1.3-1.9C above pre-industrial levels.

RCP2.6: The RCPs (Representative Concentration Pathways) are scenarios of future concentrations of greenhouse gases and other forcings. RCP2.6 (also sometimes referred to as “RCP3-PD”) is a “peak and decline” scenario where stringent mitigation… Read More

To do this, the world has been broken up into “grid cells” representing every degree latitude and every degree longitude. This results in 64,800 grid cells, which are typically about 100 kilometers wide. (In reality, they are a bit larger at the equator and smaller close to the poles.)

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Glossary
 

RCP8.5: The RCPs (Representative Concentration Pathways) are scenarios of future concentrations of greenhouse gases and other forcings. RCP8.5 is a “very high baseline” emission scenario brought about by rapid population growth, high energy demand, fossil fuel dominance and an absence of climate change policies. This scenario is the highest of the RCPs and sees atmospheric CO2 rise to around 935ppm by 2100, equivalent to 1,370ppm once other forcings are included (in CO2e). The likely range of global temperatures by 2100 for RCP8.5 is 4.0-6.1C above pre-industrial levels. The release of the Shared Socioeconomic Pathways (SSPs) has introduced a number of additional “no-new-policy” scenarios, meaning RCP8.5 is no longer the sole option available to researchers as a high-end no-mitigation pathway.

RCP8.5: The RCPs (Representative Concentration Pathways) are scenarios of future concentrations of greenhouse gases and other forcings. RCP8.5 is a “very-high baseline” emission scenario brought about by rapid population growth, high energy… Read More

The map overlay on the interactive above shows the amount of warming to expect in each grid cell based on future Representative Concentration Pathway (RCP) scenarios developed by climate scientists. These four scenarios represent different possible future emission trajectories. They range from the low-warming RCP2.6 scenario, which keeps global warming from the pre-industrial era to below 2C, up to a high-warming RCP8.5 scenario that would likely see global temperatures rise to above 4C.

§ How to use this map

Clicking on any grid cell brings up a sidebar showing the historical temperature record for that location between 1850 and 2017, both by year (in white) and with a smoothed average using 10 years of data (in red). An additional plot shows the future warming projected for that location under the four different RCP scenarios from 2000 through to 2100 – in purple, red, orange and yellow. Both historical and future temperatures are shown relative to a 1951-1980 baseline period.

The sidebar indicates both how much warming has been experienced between the first 30 years of the record and the past decade. Additionally, it shows how much warming is expected by 2100, relative to the baseline period.

Specific locations can also be typed into the search bar in the upper left corner. The past observed and future projected temperatures for each location can be downloaded by clicking on the “download csv” link. Clicking on the “home” symbol on the left will reset the interactive back to its default starting point. (Note: Users with laptops or other small screens may want to zoom out on their browsers for a better view of the map.)

§ Methodology and data sources

Observed temperatures

Temperatures based on land and ocean observations were obtained from the Berkeley Earth Surface Temperature Project’s one-degree latitude by one-degree longitude gridded monthly average temperature fields (note: large file download). These were converted into annual average temperature anomalies relative to a 1951-1980 baseline period.

These temperature estimates use observations from around 30,000 land monitoring stations, as well as thousands of ships, buoys and other monitoring systems over the ocean. Berkeley Earth uses the UK Met Office’s HadSST3 ocean temperature record as the basis for its ocean temperatures.

Observational data is available back to 1850, though for any given location data may not go back that far. Data is available from at least 1900 for most locations except Antarctica, where data is only available starting in 1950 when measurements on that continent began.

Berkeley Earth land data is homogenised – adjusted to correct for station moves, instrument changes, time of observation changes and other disruptions that stations have experienced over the past 150 years. Ocean temperature records are similarly adjusted to account for changes in the way ocean temperatures are measured, from buckets thrown over the side of ships through to engine-room intake valves and automated buoys in modern times.

These adjustments have a relatively small impact on temperatures after 1950, as discussed in the Carbon Brief explainer on temperature adjustments. The overall effect of adjustments is to increase temperatures globally prior to 1950, reducing the amount of long-term warming in the record compared to the raw readings.

Future models

Future temperature projections are taken from the Coupled Model Intercomparison Project 5 (CMIP5) multi-model average surface air temperature for each RCP scenario. CMIP5 features around 38 different climate models, though some of these represent variations of the same underlying model with different aspects included. One run from each model was used in calculating the multi-model average, with the model temperature fields obtained from KNMI Climate Explorer.

These multi-model average values are downscaled – increased in spatial resolution – to a one-degree latitude by one-degree longitude resolution to be comparable to the observations. They are converted into anomalies with respect to a 1951-1980 baseline, then aligned to the observations over the 20-year period from 1999-2018 to show the changes expected from present. Model data is shown between 2000 and 2100 in the sidebar for each grid cell.

Understanding uncertainty

Both observational temperature estimates and future projected temperature changes are subject to uncertainty. Observational uncertainties in historical temperature records from Berkeley Earth are shown in the sidebar.

Observational uncertainties can arise from a number of different factors. Incomplete coverage of observations across the Earth’s surface means that sometimes temperature anomalies in a location have to be estimates from nearby land stations or ocean measurements. The Berkeley Earth dataset uses a technique called “kriging” to create globally complete estimates of both temperature and uncertainty from observations at specific locations.

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Glossary
 

Climate sensitivity: The amount of warming we can expect when carbon dioxide in the atmosphere reaches double what it was before the industrial revolution. There are two ways to express climate sensitivity: Transient Climate Response (TCR) is the warming at Earth’s surface we can expect at the point of doubling, while Equilibrium Climate Sensitivity (ECS) is the total amount of warming once the Earth has had time to adjust fully to the extra carbon dioxide.

Climate sensitivity: The amount of warming we can expect when carbon dioxide in the atmosphere reaches double what it was before the industrial revolution. There are two ways to express climate sensitivity: Transient Climate… Read More

Future climate model projections also include significant uncertainties, chief among them the sensitivity of the climate to increased CO2. The CMIP5 models featured in the most recent IPCC report estimates climate sensitivity at between 2.1C and 4.7C per doubling of atmospheric CO2 levels, with an average sensitivity of 3.1C. The multi-model average projections shown in the sidebar only reflect this 3.1C value; users interested in the results of individual models with higher or lower sensitivity will have to use a tool such as KNMI Climate Explorer to view those results.

Individual models also show a lot more year-to-year variability than the multi-model average shown in the sidebar. Individual models have short-term variability driven by factors including El Niño and La Niña events that result in some years warmer or cooler than others. However, this short-term variability occurs at different times in different models and is largely averaged out in the multi-model average.

Technical details

The code used to calculate past observed and future projected temperatures for each of the 64,800 grid cells is available on GitHub and free for reuse or modification.

Temperature observations from the Berkeley Earth gridded one-degree latitude by one-degree longitude netCDF file are imported and converted into annual anomalies with respect to a 1951-1980 baseline period. A smoothed average is produced using a local regression (LOWESS) approach that uses a 10-year period for calculation.

Future temperature projections from the CMIP5 multi-model mean are obtained from KNMI Climate Explorer. These are statistically downscaled from their native 2.5-degree latitude by 2.5-degree longitude resolution to a one-degree latitude by one-degree longitude using bilinear interpolation – an average of nearby values. Model data is then converted into temperature anomalies with respect to a 1951-1980 baseline period. Finally, models are aligned with observations over the prior 20-year period (1999-2018) to better represent the expected change from present values.

A location name is assigned to each grid cell through a multi-step process. First, grid cell locations are geolocated using the reverse_geocoder python library. This provides information on the city, state and country closest to the grid cell’s centre. An additional “countries.geojson” file is used to identify areas over the ocean or in unpopulated areas, such as Antarctica and the high Arctic.

Finally, the centres of the grid cells are referenced against a list of all cities with a population exceeding 20,000. The name of the largest city in the grid cell is selected when multiple are present. This avoids assigning grid cell names to the settlement that happens to be closest to the geographic center of the grid cell irrespective of population.

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