Indicator Assessment

Global and European temperature

Indicator Assessment

Prod-ID: IND-4-en

Also known as: CSI 012 , CLIM 001

Published 22 Jun 2010 Last modified 11 May 2021

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Topics: Climate change adaptation

This page was archived on 25 Aug 2017 with reason: A new version has been published

Global

The global (land and ocean) average temperature increase between 1850 and 2009 was 0.74 ⁰C using combined Hadley centre and CRU datasets compared to the 1850 - 1899 period average temperature and 0.84 ⁰C using GISS dataset compared to the 1880 - 1899 period average temperature. All used temperature records show the 2000s decade (2000 - 2009) was the warmest decade.
The rate of global average temperature change has increased from around 0.06 ⁰C per decade over last 100 years, to 0.16 - 0.20 ⁰C in last decade.

The best estimates for projected global warming in this century are a further rise in the global average temperature from 1.8 to 4.0 ⁰C for different scenarios that assume no further/additional action to limit emissions. The EU global temperature target is projected to be exceeded between 2040 and 2060, taking into account all six IPCC scenarios.

Europe

Europe has warmed more than the global average. The annual average temperature for the European land area up to 2009 was 1.3 ⁰C above 1850 - 1899 average temperature, and for the combined land and ocean area 1 ⁰C above. Considering the land area, nine out of the last 12 years were among the warmest years since 1850.
High-temperature extremes like hot days, tropical nights, and heat waves have become more frequent, while low - temperature extremes (e.g. cold spells, frost days) have become less frequent in Europe. The average length of summer heat waves over Western Europe doubled over the period 1850 to 2009 and the frequency of hot days almost tripled.
The annual average temperature in Europe is projected to rise in this century with the largest warming over eastern and northern Europe in winter, and over Southern Europe in summer.
High temperature events across Europe including temperature extremes such as heat waves are projected to become more frequent, intense and longer this century, whereas winter temperature variability and the number of cold and frost extremes are projected to decrease further. According to the projections, the most affected European regions are going to be the Iberian and the Apennine Peninsula and south - eastern Europe.

Observed European annual average temperature deviations, 1850-2009, relative to the 1850-1899 average (in ºC).

Note: The European mean annual temperature deviations are in the source in relation to the base period 1961-1990. The annual deviations shown in the chart have been adjusted to be relative to the period 1850-1899.

Data source:

KNMI (http://climexp.knmi.nl/), based on Climate Research Unit (CRU) gridded datasets HadCrut3 (land and ocean) and CruTemp3 (land only) from http://www.cru.uea.ac.uk/cru/data/temperature/

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European annual, winter (December, January, February) and summer (June, July, August) mean temperature deviations, 1860-2009 (ºC)

Note: The lines refer to 10-year moving European 'land only' average.

Data source:

KNMI (http://climexp.knmi.nl/), based on Climate Research Unit (CRU) gridded datasets HadCrut3 (land and ocean) and CruTemp3 (land only) from http://www.cru.uea.ac.uk/cru/data/temperature/

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Observed changes in warm spells indices 1976-2009 (in days per decade)

Note: Warm spell duration index is defined as a period of six consecutive days with the mean daily temperature exceeding 90th percentile of the baseline temperature (average daily temperature the 1961-1990 period).

Data source:

KNMI (http://eca.knmi.nl/ensembles); Haylock et al, 2008

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Observed changes in frost days indices 1976-2009 (in days per decade)

Note: Frost day is defined as a day with an average temperature below 0 ºC. Frost days are defined as a day with an average temperature below 0 ºC.

Data source:

KNMI (http://eca.knmi.nl/ensembles); Haylock et al, 2008

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Projected average number of summer days exceeding the apparent temperature

Note: The maps show the number of summer days in Europe exceeding the apparent temperature (heat index) threshold of 40.7 °C as simulated by five ENSEMBLES Regional Climate Models for the IPCC SRES A1B emission scenario. The apparent temperature (often referred to as the heat index) represents heat stress on the human body by accounting for temperature

Data source:

EU-FP6 project ENSEMBLES; (http://eca.knmi.nl/ensembles); Haylock et al, 2008 ;

(http://www.ensembles-eu.org/) van der Linden and Mitchell, 2009, Fischer and Schaer, 2010.

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For Europe, temperature anomalies are shown for both 'land & ocean' and for 'land-only'. The first enables a comparison with the global average, the second shows temperature changes that the European citizens experience. All data are based on the datasets maintained by the Met Office Hadley Centre and Climatic Research Unit, University of East Anglia (HadCRUT3 for 'land & ocean' combined and CruTem3 for 'land only').

Annual and seasonal average in Europe

The average temperature has increased 1.3 ⁰C and 1.1 ⁰C for the European land area and European land & ocean area, respectively, comparing the trend towards 2009 with pre-industrial times (1850 - 1899) (Fig. 3). Europe has thus warmed more than the global average (i.e. 0.74 - 0.84 ⁰C compared to 1.1 ⁰C). Considering the European land, nine of the 12 years between 1998 and 2009 were among the warmest years since 1850s in Europe with 2007 as warmest year (1.5 ⁰C higher than 1850 - 1899 average temperature). The year 2009 ranked as the fifth warmest year on record with about 1.3 ⁰C higher than pre - industrial. Geographically, particularly significant warming has been observed in the past 50 years over the Iberian Peninsula, in central and north - eastern Europe and in mountainous regions (Haylock, 2008). In the past 30 years, warming was the strongest over Scandinavia, especially in winter, whereas the Iberian Peninsula warmed in summer.
On average, Europe warmed more in winter than in summer (Fig. 4). The 2009 winter was relatively cold in most of Europe (e.g. temperatures dropped down to -40 ⁰C in some locations in Scandinavia whereas in northern Italy experienced temperature of -17 ⁰C) with also extensive snowfall in many places. The spring and summer season of 2009 was warmer than the long-term average, particularly over southern Europe. Spain had the third warmest summer after the very hot summers of 2003 and 2005. Autumn, in contrary, was cold again (WMO, 2010).
Similar to the global temperature the average temperature over Europe is also projected to continue increasing over the next century. According to the ENSEMBLES project (van der Linden, 2009) the annual average temperature will increase more than global temperature, considering the A1B emission scenario (which is one of the six IPCC SRES scenarios).
In addition most of the Regional Climate Models (RCMs) results show, that the warming is projected to be the greatest over north-eastern Europe and Scandinavia in winter (December to February), and in the Mediterranean in summer (June to August) (van der Linden, 2009;). Summer temperature are projected to increase by up to 7 ⁰C in Southern Europe and 5 ⁰C in the Northern Europe comparing the period 2080 - 2100 with the 1961 - 1990 average. (van der Linden, 2009).
These results have been obtained from 25 different Regional Climate Models (RCMs) performing at 25 km spatial resolution with boundary conditions from five Global Climate Models (GCMs), all using the IPCC SRES A1B emission scenario.

Temperature extremes in Europe

High - temperature extremes like summer days, tropical nights, and heat waves have become more frequent, while low - temperature extremes (e.g. cold spells, frost days) have become less frequent in Europe (IPCC, 2007a, Fig. 5, Fig. 6).

The average length of summer heat waves over Western Europe doubled over the last 100 years and the frequency of hot days almost tripled (Della - Marta et al., 2007). In the period 1976 - 2009 increase of heat wave duration was observed in whole Europe (Fig. 5), however the trend is not significant at the majority of stations. In contrary, the significant decrease in number of frost days has been observed in most of the European area (Fig. 6).Extreme high temperature events across Europe, along with the overall warming, are projected to become more frequent, intense and longer this century (Tebaldi et al., 2006, IPCC, 2007a,b; Beniston et al., 2007; Haylock et al, 2008, van der Linden et al, 2009, Fig. 7). Geographically, the maximum temperature during summer is projected to increase far more in southern and central Europe than in northern Europe, whereas the largest reduction in the occurrence of cold extremes is projected for northern Europe (Kjellstroem et al., 2007; Beniston et al., 2007, Sillman and Roekner, 2008 Haylock et al, 2008, van der Linden, 2009). According to the ENSEMBLES RCM scenarios for 2071 - 2100 (van der Linden et al, 2009) the number of days with apparent temperature exceeding 40.7 ⁰C (heat index) will double in most parts of southern Europe.

Observed global annual average temperature deviations in the period 1850–2009 (in ºC)

Note: The annual deviations shown in the chart have been adjusted to be relative to the period 1850-1899 (for Hadley Centre/CRU) and 1880-1899 (for NASA/GISS) to better monitor the EU objective not to exceed 2 ºC above pre-industrial values. Over Europe average annual temperatures during the real pre-industrial period (1750-1799) were very similar to those during 1850-1899.

Data source:

EEA, based on NASA's GISS mean land-ocean temperature anomalies and the Hadley Center's HadCRUT3 dataset

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Rate of change of global average temperature, 1850-2009 (in ºC per decade)

Note: Lines refer to the decadal rate of change of the global temperature anomalies. Sources of the data are NASA’s GISS mean land-ocean temperature anomalies and the Hadley Center’s HadCRUT3 dataset

Data source:

EEA, based on NASA's GISS mean land-ocean temperature anomalies and the Hadley Center's HadCRUT3 dataset

Downloads and more info

In the statement on the status of the global climate (WMO, 2010), World Meteorological Organisation (WMO) has shown temperature anomalies from three datasets. For the indicator we have used two most independent datasets, maintained seperately by the Met Office Hadley Centre and Climatic Research Unit, University of East Anglia in the United Kingdom (HadCRUT3) and by the Goddard Institute for Space Studies (GISS) operated by the National Aeronautics and Space Administration (NASA) in the United States (GISTEMP).

Global assessment

The Earth has experienced considerable temperature increases in the last 100 years, especially in the most recent decades. These changes are unusual in terms of both magnitude and rate of change. The global average temperature increase between 1850 and 2009 was 0.74 ⁰C (Hadley Centre/CRU) and between 1880 and 2009 was 0.84 ⁰C according to NASA/GISS dataset, compared to the 1850 - 1899 average temperature (Hadley Centre/CRU) or 1880-1899 (NASA/GISS). This is about one third of the EU 'sustainable' target of limiting global average warming to not more than 2 ⁰C above the level in the pre-industrial period as defined for the purpose of this indicatorn (Figure 1). On the decadal scale, the 2000s decade (2000 - 2009) was warmer than the 1990s (1990 - 1999), which in turn was warmer than the 1980s (1980 - 1989) and earlier decades (WMO, 2010). 10 to 11, depending on which of the two data sets is used, out of the last 12 years (1998 - 2009) rank among the warmest years in the instrumental record, and 2005 and 1998 were the warmest two years than any other year (IPCC, 2007a, WMO, 2010).
The rate of change in the global average temperature is accelerating from 0.08 ⁰C per decade over the last 100 years, to 0.13 ⁰C per decade over the past 50 years up to 0.17 ⁰C per decade over the last 10 years (all values represent land & ocean area) (IPCC, 2007a; WMO, 2010) (Fig. 2). Thus the rate comes close to the indicative limit of 0.2 ⁰C per decade.

The global average temperature is projected to continue to increase. Globally, the projected increase in this century is between 1.8 and 4.0 ⁰C (best estimate), and is considered likely (66 % probability) to be between 1.1 and 6.4 ⁰C for the six IPCC SRES scenarios and multiple climate models (IPCC, 2007a), comparing the 2080 - 2100 average with the 1961 - 1990 average. These scenarios assume that no additional policies to limit greenhouse gas emissions are implemented (IPCC, 2007). The range results from the uncertainties in future socio-economic development and in climate models. The EU and UNFCCC Copenhagen Accord target of limiting global average warming to not more than 2.0 ⁰C above pre - industrial levels is projected to be exceeded between 2040 and 2060, for all six IPCC scenarios.

Supporting information

Indicator definition

This indicator shows absolute changes and rates of change in average near-surface temperature for the globe and for a region covering Europe. Near-surface air temperature gives one of the clearest and most consistent signals of global and regional climate change, especially in recent decades. It has been measured for many decades or even centuries at some locations and a dense network of stations across the globe, and especially in Europe, provide regular monitoring of temperature, using standardised measurements, quality control and homogeneity procedures.

This indicator provides guidance for the following policy-relevant questions:

Will the global average temperature increase stay within the UNFCCC policy target of 2.0°C above pre-industrial levels?
Will the rate of global average temperature increase stay below the indicative proposed target of 0.2°C increase per decade?

Global average annual temperature deviations, ‘anomalies’, are discussed relative to a ‘pre-industrial’ period between 1850 and 1899 (beginning of instrumental temperature records). During this time, anthropogenic greenhouse gases from the industrial revolution (between 1750 and 1850) are considered to have a relatively small influence on climate compared to natural influences. However it should be noted that owing to earlier changes in the climate due to internal and forced natural variability there was not one single pre-industrial climate and it is not clear that there is a rigorous scientific definition of the term ‘pre-industrial climate’.

Temperature changes also influence other aspects of the climate system which can impact on human activities, including sea level, intensity and frequency of floods and droughts, biota and food productivity and infectious diseases. In addition to the global average target, seasonal variations and spatial distributions of temperature change are important, for example to understand the risks that current climate poses to human and natural systems and to assess how these may be impacted by future climate change.

Units

Units are degrees Celsius (°C) and degrees Celsius per decade (°C/decade).

Baseline period

Global average annual temperature is expressed here relative to a ‘pre-industrial’ baseline period of 1850 to 1899, and this period coincides with the beginning of widespread instrumental temperature records. During this time anthropogenic GHGs (greenhouse gases) from industrial activity before 1850 had a relatively small influence on climate compared to natural influences. However, it should be noted that there is no rigorous scientific definition of the term ‘pre-industrial climate’ because climate also changed prior to 1850 due to internal and forced natural variability. Other studies sometimes use a different climatological baseline period, such as the 1971-2000 period used in parts of the IPCC Working Group One contribution to the Fifth Assessment Report (IPCC, 2013).

Rationale

Justification for indicator selection

Surface air temperature gives one of the clearest signals of global and regional climate change, and it has been measured for many decades or even centuries at some locations. For this reason it has been chosen as the indicator to monitor the “ultimate target of the United Nations Framework Convention on Climate Change.

Anthropogenic influence, mainly emissions of greenhouse gases, is responsible for most of the observed increase in global average temperature in recent decades (IPCC 2013). Natural factors, such as volcano eruptions and variations in solar activity, contribute to variations in global average temperature but they cannot explain the substantial warming during the past 50 years.

The World Meteorological Organisation defines a climate normal period as 30 years. This definition reflects the substantial climate variability on shorter time scales due to natural factors (e.g. changes in system components like the El Niño Southern Oscillation, volcanic eruptions and the solar cycle). When interpreting the time series of global mean temperature change, it is important to note that the observed record shows the combination of the long-term climate change signal and substantial year to year variability. An apparent trend in the temperature record over a few consecutive years is therefore not necessarily indicative of the long term temperature trend, which requires observations over several decades.

Global average temperature changes and the rate of change are both important determinants of the magnitude of possible effects of climate change. Furthermore, trends and projections of the annual global average temperature are easy to understand and can be related to a global target.

Understanding the spatial and seasonal distribution of climate change is important for assessing the potential impacts of climate change and associated adaptation needs. For example, temperature in Europe exhibits large differences from west (maritime) to east (continental), and from south (Mediterranean) to north (Arctic).

Scientific references

No rationale references available

Policy context and targets

Context description

This indicator provides guidance for the following policy-relevant questions:

Can the global average temperature increase stay below the EU and UNFCCC policy target of 2.0°C above pre-industrial levels?

Can the rate of global average temperature increase stay within the indicative proposed target of 0.2°C increase per decade?

The absolute change and rate of change in global average temperature are both important indicators of the severity of global climate change. Temperature changes also influence other components of the climate system which can impact on human activities, including the hydrosphere with oceans and the cryosphere.

Targets

To avoid serious climate change impacts, the European Council proposed in its Sixth Environmental Action Programme (6EAP), reaffirmed by the Environment Council and the European Council of 22-23 March 2005 (Presidency Conclusions, section IV (46)) and later in the Seventh Environmental Action Programme (7EAP, 2014) , that the global average temperature increase should be limited to not more than 2 ⁰C above pre-industrial levels. Furthermore the UNFCCC 15th conference of the parties (COP15) recognised in the Copenhagen Accord (UNFCCC, 2009) the scientific evidence for the need to keep global average temperature increase below 2 ⁰C above pre-industrial levels. In addition, some studies have proposed a 'sustainable' target of limiting the rate of anthropogenic warming to 0.1 to 0.2 ⁰ C per decade.

The target for absolute temperature change (i.e. 2 ⁰C) was initially derived from the variation of global mean temperature during the Holocene, which is the period since the last ice age during which human civilization has developed. Further studies (IPCC, 2007;Vautard, 2014) have pointed out that even a global temperature change of below the 2 ⁰C target would still result in considerable impacts. Vulnerable regions across the world, in particular in developing countries (including least developed countries, small developing island states and Africa), would be most strongly affected. The UNFCCC Copenhagen Accord (2009) therefore foresees a review in 2015 of the scientific evidence for revising the global temperature target to 1.5°C.

Mainstreaming climate change adaptation in EU policies is one of the pillars of the EU Adaptation strategy. In the Europe 2020 strategy for smart, sustainable and inclusive growth, the following is stated on combating climate change: “We must also strengthen our economies, its resilience to climate risks, and our capacity for disaster prevention and response”.

Methodology

Methodology for indicator calculation

Various data sets on trends in global and European temperature have been used for this indicator:

Global average seasonal and annual temperature: 3 datasets are used. The HadCRUT is collaborative products of the Met Office Hadley Centre (sea surface temperature) and the Climatic Research Unit (land temperature) at the University of East Anglia. The global mean annual temperature deviations are in the original source in relation to the base period 1961-1990. The annual deviations shown in the chart have been adjusted to be relative to the period 1880 to 1899 in order to better monitor the EU objective not to exceed 2oC above pre-industrial values.
The GISS surface temperature is a product of the Goddard Institute for Space Studies under NASA. The original source anomalies are calculated in the relation to the 1951 to 1980 base period. Annual deviations shown on the chart are adjusted to the 1880 to 1899 period to better monitor the EU objective, of a maximum 2 ^oC global temperature increase above the pre-industrial values. The indicator has been calculated as a combination of land and sea temperature.
The GHCN surface temperature is product of the National Climate Data Centre (NCDC) from National Oceanic and Atmospheric Administration (NOAA). Datasets are available as gridded product from 1880 onwards in monthly time step. Dataset was created from station data using the Anomaly Method, a method that uses station averages during a specified base period from which the monthly/seasonal/annual departures can be calculated. Anomalies were calculated on a monthly basis for all adjusted stations having at least 20 years of data in the 1961–1990 base period. Station anomalies were then averaged within each 5° by 5° grid box to obtain the gridded anomalies. For those grid boxes without adjusted data, anomalies were calculated from the raw station data using the same technique.

European average annual and monthly temperature: The source of the data is the latest version of the gridded CRUTEM (land only). Europe is defined as the area between 35° to 70° Northern latitude, -25° to 30° Eastern longitude, plus Turkey (35° to 40° North, 30° to 45° East). The European anomalies are in the original source in relation to the base period 1961-1990. The annual deviations shown in the chart have been adjusted to be relative to the period 1850-1899. Data source: EEA, based on CRUTEM dataset

Annual, winter (December, January, February) and summer (June, July, August) mean temperature deviations in Europe, 1860 to 2008 (^oC). The lines in the chart refer to 10-year moving average European land. Data source: EEA, based on CRUTEM datasets.

Observed changes in warm spells and frost days indices in the period 1976 to 2009; changes in the duration of warm spells in summer (days per decade) and frequency of frost days in winter (days per decade). Warm spells are defined as a period of at least six consecutive days where the mean daily temperature exceeds the baseline temperature (average daily temperature during the 1961 to 1990 period) by 5 ^oC. Frost days are defined as a day with an average temperature below 0 °C. Positive values indicate an increase in frequency and negative values a decrease in frequency. Data source: http://eca.knmi.nl/ensembles

Modelled number of heat index over Europe during summer. Heat index is defined as days with an apparent temperature above 40.7 ^oC. Apparent temperature is determined as a human-perceived equivalent temperature caused by the combined effects of air temperature and relative humidity. (left chart: 1961 to 1990 average; middle: 2021 to 2050 average, right: 2071 to 2100 average). Data source: van der Linden P., and J.F.B. Mitchell (eds.) 2009: ENSEMBLES: Climate Change and its Impacts: Summary of research and results from the ENSEMBLES project. Met Office Hadley Centre, FitzRoy Road, Exeter EX1 3PB, UK. 160pp.

Projected changes in annual (left), summer (middle) and winter (right) near-surface air temperature (°C) in the period 2071-2100 compared to the baseline period 1971-2000 for the forcing scenarios RCP 4.5 (top) and RCP 8.5 (bottom). Model simulations are based on the multi-model ensemble average of RCM simulations from the EURO-CORDEX initiative. EURO-CORDEX is the European branch of the international CORDEX initiative, which is a program sponsored by the World Climate Research Program (WRCP) to organize an internationally coordinated framework to produce improved regional climate change projections for all land regions world-wide. The CORDEX-results served as an input for climate change impact and adaptation studies within the Fifth Assessment Report (AR5) of the Intergovernmental Panel on Climate Change (IPCC).

Methodology for gap filling

Global and European average time series for monthly temperature

In the original source the long-term annual and monthly mean HadCRU global temperatures were calculated from 4349 stations for the entire period of the record. There is an irregular distribution in the time and space of available stations (i.e .denser coverage over the more populated parts of the world and increased coverage after 1950). Maps/tables giving the density of coverage through time are given for land regions by Jones (2003). The gridding method was climate anomaly method (CAM), which means the station temperature data have been converted to the anomalies according to the WMO standards (baseline period 1961-1990 and at least 15 years of station data in the period) and grid-box values have been produced by simple averaging of the individual station anomaly values within each grid box.

GISS surface temperatures were calculated using around 7200 stations from Global Historical Climatology Network, United States Historical Climatology Network (USHCN) data, and SCAR (Scientific Committee on Antarctic Research) data from Antarctic stations. Additionally satellite SST has been included for the period after 1980. Temperatures were transformed into anomalies using station normalisation based on the 1951 to 1980 baseline period. Gridding has been done with reference station method using 1200 km influence circle (Hansen et al. 2006).

Surface temperature mean anomalies from Global Historical Climatology Network-Monthly (GHCN-M) has been produced at the NCDC from 2,592 gridded data points based on a 5° by 5° grids for the entire globe. The gridded anomalies were produced from GHCN-M bias corrected data. Gridded data for every month from January 1880 to the most recent month is available. The data are temperature anomalies in degrees Celsius (Jones, 2003).

Other global climate datasets are used by the climate research community, often with a specific purpose or audience in mind, for example processed satellite Earth-observations, and climate reanalyses. Although these are not specifically constructed for climate indicator monitoring, they do show the same temperature trends described here. Recently one new global temperature dataset has been developed especially for understanding temperature trends. This is the Berkeley Earth temperature record: http://berkeleyearth.org/

Daily climate information

Although Europe has a long history in collecting climate information, datasets containing daily climate information across the continent are scarce. Furthermore, accurate climate analysis requires long term time series without artificial breaks. The objective of the ECA project was to compile such a data set, consisting of homogeneous, long-term daily climate information. To ensure a uniform analysis method and data handling, data were centrally collected from about 200 meteorological stations in most countries of Europe and parts of the Middle East. Furthermore the data were processed and analysed at one institute (i.e. KNMI) (Klok et.al. , 2008).

In order to ensure the quality of the ECA&D climate data set:

Statistical homogeneity tests have been applied to detect breaks in the time series;
the meta-information accompanied with the data has intensively been analysed, e.g. to check whether observed trends were not triggered by, for example, movements of stations;
the final data set has been compared with other data sets, like the aforementioned data set of Climatic Research Unit; and
findings of the different exercises have been discussed during workshops with representatives of countries.

Global and European average time series for monthly temperature

Grid values of HadCRUT, GISTEMP and GHCN data sets have been gridded using different interpolation techniques. Each grid-box value for the HadCRUT dataset is the mean of all available station anomaly values, except that station outliers in excess of five standard deviations are omitted (Brohan et al., 2005). GISTEMP temperature anomaly data are gridded into 8000 grid cells using reference station interpolation method with 1200 km influence circle (Hansen et al. 2006). GHCN monthly data consists of 2,592 gridded data points produced on a 5° by 5° basis for the entire globe (Jones, 2003).

Methodology references

No methodology references available.

Uncertainties

Methodology uncertainty

The observed increase in average air temperature, particularly during recent decades, is one of the clearest signals of global climate change.

Temperature has been measured over the centuries. There is a range of different methodologies which give similar results suggesting that uncertainty is relatively low. Three data sets have been presented here for the global temperature indicator. Global temperatures from HadCRUT, GISTEMP, and GHCN have been homogenized to minimise the effects of changing measurement methodologies and location.

Data sets uncertainty

Each observation station follows international standards for taking observations set out by WMO. Each National Meteorological Service provides reports on how its data are collected and processed to ensure consistency. This includes recording information about the local environment around the observation station and any changes to that environment. This is important for ensuring the required data accuracy and performing homogeneity tests and adjustments. There are additional uncertainties because temperatures over large areas of the Earth are not observed as a matter of routine. These elements are taken into account by factoring the uncertainty into global average temperature calculations, thereby producing a temperature range rather than one uniquely definite figure (WMO, 2013). The uncertainty of temperature data has decreased over recent decades due to wider use of agreed methodologies and denser monitoring networks. Uncertainty of the temperature data comes from sampling error, temperature bias effect and from the effect of the limited observation coverage. Annual values of global and European temperature are approximately accurate to +/- 0.05 degrees C (two standard errors) for the period since 1951. They are about four times as uncertain during the 1850s, with the accuracy improving gradually between 1860 and 1950 except for temporary deteriorations during data-sparse, wartime intervals. Estimating accuracy is difficult as the individual grid-boxes are not independent of each other and the accuracy of each grid-box time series varies through time (although the variance adjustment has reduced this influence to a large extent). The issue is discussed extensively by Jones et al. (2003), Brohan et al. (2005), and Hansen et al. (2006).

Rationale uncertainty

According to the IPCC 4^th Assessment Report (IPCC, 2007), there is very high confidence that the net effect of human activities since 1750 has been one of warming. Most of the observed increase in global average temperatures since the mid-20th century is very likely due to the observed increase in anthropogenic GHG concentrations. Moreover, it is extremely likely that more than half of the observed increase in global average surface temperature from 1951 to 2010 was caused by the anthropogenic increase in greenhouse gas concentrations and other anthropogenic forcings together. The best estimate of the human-induced contribution to warming is similar to the observed warming over this period (IPCC, 2013).

Data sources

HadCRUT4 (Met Office, CRU)
provided by Met Office United Kingdom
Global Land-Ocean Temperature Index (NASA)
provided by NASA
Annual Global (Land and Ocean) temperature anomalies
provided by National Oceanic and Atmospheric Administration (NOAA)
ENSEMBLES FP6 project (dataset URL is not available)
provided by ENSEMBLE FP6 project
EURO-CORDEX Data
provided by EURO-CORDEX
CRUTEM4 dataset (Met Office, CRU)
provided by Met Office United Kingdom
NCEI Data and Products (NOAA)
provided by National Oceanic and Atmospheric Administration (NOAA)
European Climate Assessment & Dataset: The daily European land temperature
provided by Royal Netherlands Meteorological Institute (KNMI)

Other info

DPSIR: State
Typology: Performance indicator (Type B - Does it matter?)

Indicator codes

CSI 012
CLIM 001

Frequency of updates

Updates are scheduled once per year

EEA Contact Info info@eea.europa.eu

Permalinks

Permalink to this version: 33d27d4213f4c84e3e6875f5d7eac804
Permalink to latest version: IND-4-en

Older versions

20 Mar 2009 - Global and European temperature

08 Sep 2008 - Temperature extremes in Europe

25 Apr 2008 - Global and European temperature

06 Oct 2005 - Global and European temperature

Geographic coverage

Albania Andorra Armenia Austria Azerbaijan Belarus Belgium Bosnia and Herzegovina Bulgaria Croatia Cyprus Czechia Denmark Estonia Finland France Georgia Germany Greece Hungary Iceland Ireland Italy Kazakhstan Latvia Liechtenstein Lithuania Luxembourg Malta Moldova Monaco Montenegro Netherlands North Macedonia Norway Poland Portugal Romania Russia San Marino Serbia Slovakia Slovenia Spain Sweden Switzerland Turkey Ukraine United Kingdom

Temporal coverage

1850-2098

For references, please go to https://www.eea.europa.eu/data-and-maps/indicators/global-and-european-temperature/global-and-european-temperature-assessment-3 or scan the QR code.

PDF generated on 19 Apr 2024, 08:24 PM

Dates

First draft created:

29 Mar 2010, 11:36 AM

Publish date:

22 Jun 2010, 12:00 AM

Last modified:

11 May 2021, 11:43 AM

Topics

Topics: Climate change adaptation