Development of a Quality-Controlled and Homogenised Long-Term Daily Maximum and Minimum Air Temperature Network Dataset for Ireland

Abstract

Accurate long-term daily maximum and minimum air temperature series are needed to assess the frequency, intensity, distribution, and duration of extreme climatic events. However, quality control and homogenisation procedures are required to minimise errors and inhomogeneities in climate series before the commencement of climate data analysis. A semi-automatic quality control procedure consisting of climate consistency, internal consistency, day-to-day step-change, and persistency tests was applied for 12 long-term series registered in Ireland from 1831–1968, Armagh Observatory (Northern Ireland) from 1844–2018, and for 21 short-term series dating to the mid-19th century. There were 976,786 observations quality-controlled, and 27,854 (2.9%) values flagged. Of the flagged records, 98.5% (n = 27,446) were validated, 1.4% (n = 380) corrected and 0.1% (n = 28) deleted. The historical long-term quality-controlled series were merged with the modern series quality-controlled by Met Éireann and homogenised using the software MASHv3.03 in combination with station metadata for 1885–2018. The series presented better homogenisation outcomes when homogenised as part of smaller regional networks rather than as a national network. The homogenisation of daily, monthly, seasonal, and annual series improved for all stations, and the homogenised records showed stronger correlations with the Central England long-term temperature series.

1. Introduction

The Island of Ireland has a great heritage of meteorological observations dating back to the 17th century, although the majority of the records remain as paper data-sources which need to be rescued to fill critical gaps in climate research [1]. A total of 21 short-term and 12 long-term daily maximum air temperature (MAX) and daily minimum air temperature (MIN) series registered in the Island of Ireland and dating back to the 19th century were rescued from multiple data-sources and digitised [2,3]. The historical data will be analysed to assess the frequency, duration, intensity, and distribution of extreme air temperature indices as recommended by the Expert Team on Climate Change Detection and Indices (ETCCDI), as well as long-term trends of heat waves and cold waves in Ireland [4,5,6].

However, systematic, random, gross, or micrometeorological errors can influence the quality of climate datasets [7,8]. Quality control of instrumental datasets involves checking for data keying errors and detecting other errors which can be deleted or corrected to ensure the accuracy and consistency of data. Data validation applies quality control tests to flag, and subsequently inspect, suspicious data [8].

Quality control refers to short-term errors that may affect days or weeks, while inhomogeneities refer to long-term changes in the observing system [9]. Changes of the observer, relocation of a station, changes in thermometers, thermometer screens, station surroundings, or the replacement of manual with automatic weather stations can affect the homogeneity of long-term series [9,10,11]. The assessment of climate data homogeneity is necessary to minimise artificial effects on climate data series and ensure that any variability, change, and trends result from weather and climate variations [12,13]. The World Meteorological Organization recommends applying quality control and homogenisation procedures before climate data analysis [7,14,15]. The assessment of quality and homogenisation of climate data is advised for international data exchange, data repositories, scientific analysis, and the generation of products, such as climate normals or gridded datasets. Statistical homogenisation procedures aim to detect and correct (minimise) artificial bias in the climate series and validate the results [9,15,16]. Detection corresponds to the application of statistical methodologies and the examination of station metadata to identify non-climate inhomogeneities in the data. During the adjustment (correction), statistical approaches are employed to reduce inhomogeneities in order to achieve comparable series with the modern data. Nevertheless, small inhomogeneities may remain in the adjusted series [9]. Thus, validation is essential to review the homogenised data against the original data [16].

This research applied quality-control procedures to 13 long-term and 21 short-term historical daily MAX and MIN series dating back to the 19th century and homogenised 11 long-term daily MAX and MIN series from 1885–2018 on the island of Ireland to develop series suitable for the assessment of extreme air temperature indices [4,5,6].

2. Material and Methods

2.1. Study Area

Air temperatures in Ireland reflect oceanic, topographic, and latitudinal controls [17]. The proximity of the Atlantic Ocean and the westerly atmospheric circulation of the middle latitudes are the major controls on Ireland’s climate [17]. The influence of the North Atlantic Current makes Ireland experience a subdued range of temperatures compared to more continental countries at the same latitude [18]. The contrast in the air temperature gradient between coastal and inland areas is clear in the winter, whereas the latitudinal influence in the air temperature is greater in the summer [17,18]. Hills and mountains allow shelter from strong winds and direct oceanic influences [17]. For instance, Markree Observatory, although sited ~7 km from the Atlantic Ocean, presents low minimum air temperatures and large diurnal air temperature ranges due to the surrounding topography that shields the site from the influence of the Atlantic Ocean and the prevailing south-westerly winds [19].

2.2. Quality Control

The historical network dating to the 19th century includes 14 long-term (

Table 1. Historical quality-controlled long-term daily MAX and MIN series.

Series	Station No.	County	Years
Armagh Observatory	1	Armagh	1844–2018
Belmullet	2	Mayo	1884–1899
			1956
Birr (second order station)	3	Offaly	1872–1911
Birr (telegraphic station)			1880–1956
Blacksod Point	4	Mayo	1899–1956
Botanic Gardens, Glasnevin-Dublin	5	Dublin	1834
			1847–1958
Botanic Gardens, Glasnevin-Dublin (NLI series)			1882–1952
Fitzwilliam Square, Dublin	6	Dublin	1971–1937
Killarney	7	Kerry	1881–1898
			1920–1933
Markree	8	Sligo	1850–1852
			1855–1856
			1874–1968
Markree (new screen)			1953–1954
Malin Head	9	Donegal	1885–1955
NUI Galway	10	Galway	1851–1852
			1861–1952
Phoenix Park, Dublin	11	Dublin	1831–1852
			1855–1959
Phoenix Park, Dublin (outside observatory)			1842–1847
Phoenix Park, Dublin (Larcom papers)			1853–1855
Phoenix Park, Dublin (comparison sheet)			1856–1860
Phoenix Park, Dublin (Bilham screen)			1953–1955
Roches Point	12	Cork	1872–1956
Roches Point (new station)			1955
Valentia Observatory (Valentia Island)	13	Kerry	1850–1851
			1872–1892
Valentia Observatory (Caherciveen)	14	Kerry	1892–1943
Valentia Observatory (Valentia Island, second order station)	13	Kerry	1883–1892
Valentia Observatory (Caherciveen, second order station)	14	Kerry	1892–1909
Trinity College Dublin	15	Dublin	1840–1851
			1855–1856
			1904–1959

) and 21 short-term (

Table 2. Historical quality-controlled short-term daily MAX and MIN series.

Series	Station No.	County	Years
Athy	16	Kildare	1850–1852
Belfast	17	Down	1851–1852
Blackrock	18	Cork	1881–1890
Buncrana	19	Donegal	1850–1851
Castletownsend	20	Cork	1850–1851
Commercial Buildings, Dublin	21	Dublin	1850–1858
Courtown	22	Wexford	1850–1852
Donaghadee	23	Donegal	1850–1852
Dunmore East	24	Waterford	1850–1851
Glendooen	25	Donegal	1865–1870
Grafton Street, Dublin	26	Dublin	1843–1849
Inishgort Island	27	Mayo	1851–1852
Kilkenny	28	Kilkenny	1862–1864
Killough	29	Down	1851–1852
			1854
Killybegs	30	Donegal	1850–1851
Kilrush	31	Clare	1850–1851
Portarlington	32	Laois/Offaly	1845–1864
Portrush	33	Antrim	1850–1852
Royal College of Surgeons, Dublin	34	Dublin	1841–1857
Royal Dublin Observatory (Dunsink)	35	Dublin	1851
Scattery (Inis Cathaigh)	36	Clare	1850–1852

) daily MAX and MIN series across Ireland (Figure 1). Met Éireann has performed quality control tests on daily MAX and MIN data of the 12 long-term series from 1960 onwards [20]. Therefore, this research applies similar quality control tests to the rescued historical data from 1831–1968 (Table 1, Figure 1). The MAX and MIN data registered at Armagh Observatory (Northern Ireland) in 1844–2018 [21,22] were also subjected to quality control procedures as part of this research.

2.2.1. Quality Control Tests

A semi-automatic quality control procedure was used so that doubtful MAX and MIN data were automatically flagged, and assessment of flagged data was conducted manually. The quality control tests comprise climate consistency, internal consistency, day-to-day step-change, and persistence, written in R software to automatically flag suspect MAX and MIN values. These tests have been explored by [24]. Met Éireann applied these same quality control tests to daily MAX and MIN series registered in Ireland from 1961 to 2010 [20].

The quality control tests were defined as follows (

Table 3. Quality control tests.

Flags	Definition
Flag 1	Lower daily MIN threshold exceedance.
Flag 2	Upper daily MIN threshold exceedance.
Flag 3	Lower daily MAX threshold exceedance.
Flag 4	Upper daily MAX threshold exceedance.
Flag 5	Daily MAX lower than the MIN.
Flag 6	Step-change in daily MIN higher than 4.5 standard deviations from the mean.
Flag 7	Step-change in daily MAX higher than 4.5 standard deviations from the mean.
Flag 8	Step-change in daily MIN and MAX higher than 4.5 standard deviations from the mean.
Flag 9	Three or more consecutive days with the same daily MIN.
Flag 10	Three or more consecutive days with the same daily MAX.
Flag 11	Three or more consecutive days with the same daily MIN and MAX.

):

Climate consistency (flags nos. 1–4). These tests check that daily MAX and MIN data are defined by upper and lower thresholds for each month. The upper and lower daily MAX and MIN thresholds were determined by Met Éireann according to Ireland’s climate [20].

Internal consistency (flag no. 5). This test assures that daily MAX and MIN data for a given day are internally consistent. If the MAX is lower than the MIN for a given day, both observations are flagged.

Day-to-day step-change (flags nos. 6–8). These tests check if the daily step-change falls within the expected lower and upper limits of the daily change rate for a given month, defined as 4.5 standard deviations from the mean.

Persistence (flags nos. 9–11). These tests flag three or more consecutive days with the same air temperature values. The test is essential to detect possible errors caused by the non-reading and non-resetting of thermometers.

2.2.2. Manual Assessment of Flagged Data

Each flagged value was manually checked to keep false positive values to a minimum. Although it is time-consuming, the manual verification of flagged values is necessary to preserve extreme air temperature events, which otherwise could be erroneously considered as outliers in a fully automated quality control procedure [25,26]. Data corrections were carefully evaluated to prevent erroneous adjustments of unique observations [27].

The flagged daily MAX and MIN data were manually compared with the dry-bulb air temperature values in the original data-source to evaluate the consistency between thermometers. The daily MAX (MIN) must be equal or higher (lower) than the dry-bulb thermometer on the observation day and the previous day, considering the 24 h period, or the last time when the MAX (MIN) thermometer was reset in case of more than one observation in a 24 h period. The flagged daily MAX and MIN data were manually verified in the image of the original data-source to identify possible errors in the meteorological register, assess observer’s notes, evaluate general weather remarks, and compare the consistency of the MAX and MIN records with the dry-bulb readings. The manual comparison of flagged data with observations registered at one or more surrounding stations was completed when flagged MAX and MIN data disagreed with the dry-bulb readings.

Station metadata were also examined during the assessment of the consistency between the flagged data and dry-bulb readings to avoid inaccurate validation, correction, or deletion of flagged data. Overlapping data-sources were consulted in addition to the handwritten meteorological registers that were used for data rescue. Extreme absolute MAX and MIN data registered at other stations, e.g., [28], and articles on past extreme air temperature events, e.g., [29], were examined since publications such as these include the analysis of absolute MAX and MIN data at various locations. Relevant documentary sources include historical newspapers with references to extreme weather events (Figure 2). Other observed climate elements in the instrumental meteorological logbooks, such as the register of snow or snow depth records and observer’s notes on the frozen wet-bulb, are essential for validating low MIN values. Historical daily synoptic charts and weather summaries in the Daily Weather Report and reanalysis at Wetterzentrale [30] were consulted. The station metadata examined included observer’s notes, weather remarks, and inspections of the stations on observers, instruments, observation practices, and station surroundings [2].

Following the manual examination of the flagged values as described above, flagged values were validated (retained), corrected, or deleted in case of error and unfeasibility to ensure accuracy. Concerning the corrections, if the flagged MAX (MIN) was initially lower (higher) than the dry-bulb on the previous and/or observation days, the flagged reading was replaced with the same or +1 °F (–1 °F) value higher than the dry-bulb reading on the previous and/or observation days, since the historical readings were recorded as degrees Fahrenheit. The correction was converted to degrees Celsius before adding it to the quality-controlled dataset. The correction was based on the manual comparison of MAX and MIN registers at neighbouring stations with a similar observation time and a similar elevation above sea level. In this case, it was confirmed that the dry-bulb readings had no gross instrumental errors and were higher than the wet-bulb records. Flagged values were corrected if possible, rather than deleted from the dataset. The quality-control script was then applied after the correction of flagged data to ensure no errors were inserted in the quality-controlled dataset.

2.3. Homogenisation

2.3.1. Selection of Homogenisation Software

The criteria for selecting the homogenisation software comprised freely available software applicable to the daily MAX and MIN data, automatic use of station metadata, and a relative homogenisation method that would allow future updates with recent observations. While homogenisation of monthly, seasonal, and annual data has been widely researched and performed with satisfactory results, the homogenisation of daily air temperature data constitutes a challenge [15]. Various homogenisation software packages were benchmarked in the European Cooperation in Science and Technology (COST) program [32]. This research highlighted MASH (Multiple Analysis of Series for Homogenisation) as one of the best methods for monthly homogenisation and production of high-quality time series [32]. The “excellent performance” of the software MASH was also reported by [9] (p. 39) and by [33]. The software MASH has also been successfully applied for the homogenisation of daily air temperature data, e.g., [34,35,36]. Thus, the interactive and automatic homogenisation software package MASHv3.03 [16,37] was chosen to homogenise daily, monthly, seasonal, and annual long-term MAX and MIN series.

2.3.2. Homogenisation Procedure

MASHv3.03 is a Windows-executable, relative test homogenisation method that uses an additive model for homogenisation of air temperature series. Generalised least square estimation is employed to estimate the unknown climate change signal in each candidate series with a reference series, which can be changed through the procedure to optimise homogenisation [16].

Station metadata can be used to automatically identify potential dates of break-points, although MASHv3.03 is effective in detecting break-points with and without station metadata [38]. MASHv3.03 has an iterative multiple break-point detection procedure based on hypothesis testing, point estimation, and confidence intervals. Correction factors are automatically estimated according to point estimation and based on confidence intervals to correct the series [39,40]. MASHv3.03 applies spatial interpolation with optimal weighting factors to fill data gaps.

The main steps in MASHv3.03 include the calculation of the monthly series derived from the daily series. During the homogenisation of the monthly series, the mean is homogenised. Daily inhomogeneities are smooth estimated, considering the detected monthly inhomogeneities. The software allows for automatic correction of the daily series, posterior automatic quality control of the homogenised series, and automatic missing daily data gaps completion, which procedures were applied to the 11 series.

A total of 11 long-term quality-controlled MAX and MIN series (

Table 4. Long-term MAX and MIN series tested for homogenisation. All series are part of the national network. Series are included in regional networks: Dublin/Midlands and Western.

Series	Regional Network	Gaps Max (%)	Gaps Min (%)
Armagh Observatory	Dublin/Midlands	0.02	0.04
Birr/Gurteen	Dublin/Midlands	0.1	0.05
Blacksod Point/Belmullet	Western	0.48	0.49
Botanic Gardens, Glasnevin	Dublin/Midlands	2.84	2.95
Dublin (Fitzwilliam Square/Trinity College Dublin/Merrion Square)	Dublin/Midlands	1.16	1.23
Malin Head	Western	0.12	0.1
Markree	Western	9.14	9.10
NUI Galway/Athenry	Western	12.31	12.32
Phoenix Park, Dublin	Dublin/Midlands	0.07	0.13
Roches Point	Western	5.49	5.37
Valentia Observatory	Western	0.02	0.01

) were tested for homogeneity at daily, monthly, seasonal, and annual resolutions in the period 1885–2018. The historical data quality-controlled in this research (1885–1960) were merged with the quality-controlled data following the same quality control tests by Met Éireann for 1961–2010 [20] and 2011–2018. Despite the availability of quality-controlled data from 1831, the series were tested for homogenisation from 1885 due to observational gaps, lack of a dense station network, incomplete station metadata, and employment of historical instrumentation and observational practices in the earlier records. By the late-19th century, the meteorological stations were required to follow standard instrumental and observational practices and were frequently inspected [2]. The Stevenson screen was introduced in the 1880s for most of the stations.

The Fitzwilliam Square, Dublin (1885–1903), Trinity College Dublin (1904–1970), and Merrion Square, Dublin (1971–2018) series, all located within Dublin city centre, were merged to create a more extended series for Dublin city (1885–2018) (Table 4). The NUI Galway records (1885–2011) were merged with Athenry (2012–2018), and the Birr series (1885–2008) were combined with the automatic records of Gurteen Agricultural College (2009–2018) to complete data coverage to 2018. Due to a high percentage of missing data (MAX: 54.8%; MIN: 55.1%), the Killarney series were not included in the homogenisation.

The homogenisation of the MAX and MIN series was performed separately. The correlations for daily MAX range from r = 0.987 (Merrion Square, Dublin and Glasnevin, Merrion Square, Dublin, and Trinity College Dublin) to r = 0.860 (Malin Head and Roches Point). For the MIN series, the correlations range from r = 0.983 (Fitzwilliam Square, Dublin and Trinity College Dublin) to r = 0.824 (Malin Head and Valentia Observatory).

2.3.3. Comparison of Station Networks: National versus Regional

Two homogenisation methodologies were compared: one national network versus two regional networks. The homogeneity testing of the Dublin/Midlands and Western regional networks was performed to compare the outcomes of the same stations included in the national network, thus with more reference series. The national network has 11 stations (Table 4) and contains 2.9% (n = 15,474) missing data for the MAX series and 2.9% (n = 15,559) missing data for the MIN series. The Dublin/Midlands network incorporates the series Phoenix Park, Dublin city, Botanic Gardens (Glasnevin, Dublin), Armagh Observatory, and Birr/Gurteen. This regional network has 0.8% (n = 2053) missing data for the MAX series and 0.9% (n = 2152) missing data for the MIN series. The Western network includes the series Malin Head, Markree, Belmullet/Blacksod Point, NUI Galway/Athenry, Valentia Observatory, and Roches Point. The Western network contains 4.6% (n = 13,481) missing data for the MAX series and 4.6% (n = 13,407) missing data for the MIN series.

The following criteria were assessed to compare the homogenisation outcomes of the national and regional networks: (1) changes in MAX and MIN trends in comparison to raw data in the seasonal and annual series, e.g., to ensure that general trends are preserved; (2) homogenisation test statistics; (3) conservation of extremes, e.g., summer days and frost days; (4) alignment of inhomogeneities with known station relocations; and (5) Pearson correlations with the Central England MAX and MIN series [41]. Good homogenisation results require that the test statistics (TS) after homogenisation (TSa) should be near or lower than the critical value and lower than the test statistics before homogenisation (TSb) [16]. The analysis of TSb and TSa is performed for each candidate series and the whole network of series. The relative change of the TS is obtained as (TSb–TSa)/TSb [16]. The summary of TS is part of the automatic verification of homogenisation, which is integrated into the software MASHv3.03 to ensure that the homogeneity of the series has increased during the statistical procedures. The relative modification of the series and the statistics for estimated inhomogeneities (which are also outputs produced by MASHv3.03 in the verification statistics to characterise inhomogeneities [16]) were analysed. The number of days with daily minimum air temperature below 0 °C (frost days) and daily maximum air temperature above 25 °C (summer days) were examined in the quality-controlled and homogenised series (with gaps as presented before homogeneity testing to assess the impact of the homogenisation on the daily data). Comparing raw and homogenised series with independent records, such as climate reconstruction from proxies, documentary sources, or other instrumental records, is essential to examine the quality of homogenised data [15]. Therefore, the Pearson correlations between each MAX and MIN homogenised series were compared to the Central England seasonal and annual series.

3. Results

3.1. Quality Control

In total, 976,786 observations were quality-controlled and 27,854 (2.9%) values were flagged. Of the flags, 16,156 were MAX and 11,698 were MIN. The flagged data can be summarised as follows: 51 for climate consistency (

Table A1. Flagged lower daily MIN threshold exceedance (flag 1) and the dry-bulb thermometer registered on previous and observation days.

Station	Year	Month	Day	MIN (°C)	MAX (°C)	Dry-Bulb Previous Day (°C)	Dry-Bulb Obs. Day (°C)	Dry-Bulb Obs. Day (°C)	Decision (°C)
Armagh Observatory	1947	March	3.	−12.4.	1.9.	−4.8.	−9.4.	−3.2.	Validated (−12.4)
Killarney	1882	July	2.	−1.1.	21.1.	17.2.	17.9.	NA.	Deleted
	1882	July	3	−1.1	21.2	17.9	18.3	NA	Deleted
	1882	July	22	−1.1	21.1	18.3	20.1	NA	Deleted
Markree	1947	March	1	−16.7	4.4	0	−0.8	0	Validated (−16.7)
	1947	March	2	−13.3	3.9	0	−1.1	−1.7	Validated (−13.3)
	1947	March	3	−17.2	3.9	−1.7	−1.7	−0.1	Validated (−17.2)
	1947	March	6	−13.9	5.6	−0.1	3.9	1.7	Validated (−13.9)

Relative to the dry-bulb air temperature observations in the given tables, NA means that no readings are available, or that the values fall outside of the 24 h period used to assess the consistency between the maximum, minimum, and dry-bulb thermometers.

,

Table A2. Flagged upper daily MIN threshold exceedance (flag 2) and the dry-bulb thermometer registered on previous and observation days.

Station	Year	Month	Day	MIN (°C)	MAX (°C)	Dry-Bulb Previous Day (°C)	Dry-Bulb Morning Obs. Day (°C)	Dry-Bulb Evening Obs. Day (°C)	Decision (°C)
Botanic Gardens, Glasnevin	1868	May	31	16.7	21.1	15.6	NA	16.7	Corrected (5.6)
	1878	March	1	15.4	15.1	13.2	NA	15	Corrected (9.9)
	1927	November	2	15.1	20.2	16.4	16.7	16.4	Validated (15.1)
Botanic Gardens (NLI), Glasnevin	1927	November	2	15.1	20.2	13.7 A	16.7	NA	Validated (15.1)
	1944	February	15	14.1	11.8	0.1 B	4.4	NA	Corrected (−2.6)
Fitzwilliam Square, Dublin	1927	November	2	15.6	17.8	16.3	16.3	15.8	Validated (15.6)
NUI Galway	1881	November	14	15.6	11.7	9.4	7.8	NA	Corrected (11.7)
	1889	July	4	25	26.7	22.8	22.2	NA	Corrected (10.6)
	1939	May	28	17.2	23.3	14.4	17.8	NA	Corrected (11.7)
	1939	May	29	16.7	25.6	17.8	16.7	NA	Corrected (11.1)
Portarlington	1846	October	3	18.3	13.9	11.9	10.1	NA	Corrected (7.2)
Valentia Observatory	1890	May	25	16.7	18.3	17.2 C	17.8	NA	Validated (16.7)

^A Botanic Gardens (NLI), Glasnevin: dry-bulb on the previous day at 09:00 (16.4 °C). ^B Botanic Gardens (NLI), Glasnevin: dry-bulb on the previous day at 09:00 (−0.6 °C). ^C Valentia Observatory: dry-bulb on the previous day at 08:00 (17.2 °C), 14:00 (19.4 °C), and 18:00 (17.2 °C).

,

Table A3. Flagged lower daily MAX threshold exceedance (flag 3) and the dry-bulb thermometer registered on previous and observation days.

Station	Year	Month	Day	MIN (°C)	MAX (°C)	Dry-Bulb Previous Day (°C)	Dry-Bulb Morning Obs. Day (°C)	Dry-Bulb Evening Obs. Day (°C)	Decision (°C)
Armagh Observatory	1859	October	24	−2.2	3	−0.8	−0.2	−0.1	Validated (3)
	1859	October	25	−1.8	2.3	−0.1	−1.9	0.2	Validated (2.3)
	1870	May	4	3.9	1.2	6.7	8.5	7.2	Corrected (12.8)
	1962	May	31	−1	2.9	12.6 A	51.8	NA	Corrected (13.2)
Blacksod Point	1917	April	1	−2.8	−0.6	−2.2 B	−2.8	−2.2	Validated (−0.6)
Botanic Gardens, Glasnevin	1859	October	23	−1.1	3.3	3.9	NA	2.8	Validated (3.3)
	1859	October	24	−2.2	2.8	2.8	NA	1.1	Validated (2.8)
	1873	October	24	−0.6	3.9	7.2	NA	4.4	Corrected (7.2)
	1880	October	20	−2.8	1.7	5.4	2.1	NA	Corrected (1.7)
	1880	October	21	−2.2	2.2	2.1	2.4	NA	Corrected (2.2)
	1880	October	30	3.7	−2.2	3.9	3.9	NA	Corrected (3.7)
Botanic Gardens (NLI), Glasnevin	1949	October	22	2	2.2	7.2 C	2.2	NA	Corrected (7.8)
Commercial Buildings, Dublin	1856	April	24	6.1	−2.8	13.3	13.3	NA	Corrected (13.9)
Grafton Street, Dublin	1848	October	19	0.6	3.9	NA	NA	NA	Corrected (9.4)
Malin Head	1917	April	10	−2.2	0.6	−2.2 D	−1.7	NA	Validated (0.6)
NUI Galway	1881	March	30	−3.9	−1.1	3.3	1.7	NA	Corrected (3.3)
	1930	December	31	−1.1	−15.6	4.4	4.4	NA	Corrected (7.2)
	1938	August	21	NA	7.8	12.8	14.4	NA	Corrected (14.4)
	1951	March	27	1.1	−0.6	5	6.1	NA	Corrected (6.1)
Phoenix Park, Dublin	1855	February	15	−14.9	−11.9	NA	NA	NA	Validated (−11.9)
	1856	September	7	9.4	4.4	17.2 E	13.3	NA	Corrected (17.2)
	1859	October	25	−3.1	1.6	0.7 F	−1.9	NA	Validated (1.6)

^A Dry-bulb on the previous day at 09:00 (12.6 °C) and 21:00 (7.0 °C). ^B Dry-bulb on the previous day at 07:00 (−2.2 °C), 13:00 (−2.8 °C), 18:00 (−2.2 °C), and 21:00 (−2.2 °C). ^C Dry-bulb on the previous day at 09:00 and 21:00 (7.2 °C). ^D Dry-bulb on the previous day at 07:00 (−2.2 °C), 13:00 (−0.6 °C), 18:00 (−2.2 °C) and 21:00 (−1.7 °C). ^E Dry-bulb on the previous day at 09:30 and 15:30 (17.2 °C). ^F Dry-bulb on the previous day at 09:30 (0.7 °C) and 15:30 (0.8 °C).

and

Table A4. Flagged upper daily MAX threshold exceedance (flag 4) and the dry-bulb thermometer registered on previous and observation days.

Station	Year	Month	Day	MIN (°C)	MAX (°C)	Dry-Bulb Previous Day (°C)	Dry-Bulb Morning Obs. Day (°C)	Dry-Bulb Evening Obs. Day (°C)	Decision (°C)
Blackrock	1885	July	26	16.1	33.9	NA	NA	NA	Deleted
	1885	July	27	13.9	33.3	NA	NA	NA	Deleted
Dunmore	1851	June	29	17.8	33.3	18.9 A	19.4	NA	Validated (33.3)
NUI Galway	1895	October	1	12.2	24.4	14.4	15.6	NA	Validated (24.4)
Markree	1851	June	27	15.4	33.1	12.4	21.9	18	Validated (33.1)
	1851	June	28	15.4	33.3	18	23.4	19.4	Validated (33.3)
Phoenix Park, Dublin	1876	July	16	4.9	33.5	23.1 B	26.9	NA	Validated (33.5)
	1959	October	3	15.3	24.2	18.8 C	18.9	NA	Validated (24.2)
Royal College of Surgeons, Dublin	1852	March	23	7.5	35	NA	NA	NA	Corrected (15)

^A Dry-bulb on the previous day at 09:00 (18.9 °C) and 21:00 (18.9 °C). ^B Dry-bulb on the previous day at 09:30 (23.1 °C) and 15:30 (25.1 °C). ^C Dry-bulb on the previous day at 09:00 (18.8 °C) and 21:00 (16.7 °C).

in Appendix A), 264 for internal consistency (

Table A5. Total of flagged daily MAX and MIN data, which failed the quality control test flag 5 per station.

Station	Total Flagged	Total Validated	Total Corrected	Total Deleted
Armagh Observatory	2	1	1	0
Belmullet/Blacksod	46	0	37	0
Birr	16	6	10	0
Blackrock	2	1	1	0
Botanic Gardens, Dublin	56	13	35	8
Commercial Buildings, Dublin	4	1	3	0
Grafton Street, Dublin	4	1	3	0
Killarney	6	3	3	0
Malin Head	8	4	4	0
Markree Observatory	18	4	14	0
NUI Galway	42	13	29	0
Phoenix Park, Dublin	24	11	10	3
Portarlington	6	2	4	0
Royal College of Surgeons, Dublin	2	0	2	0
Roches Point	10	5	5	0
Trinity College Dublin	4	2	2	0
Valentia Observatory	14	7	7	0

), 13 for a day-to-day step-change (

Table A6. Flagged step-change in daily MIN higher than 4.5 standard deviations from the mean (flag 6) and the dry-bulb thermometer registered on previous and observation days.

Step Change	Station	Year	Month	Day	MIN (°C)	MAX (°C)	Dry-Bulb Previous Day (°C)	Dry-Bulb Morning Obs. Day (°C)	Dry-Bulb Evening Obs. Day (°C)	Decision (°C)
Previous day	Armagh Observatory	2010	December	26	−10.9	7	−10.9	3.1	NA
Flagged				27	3	8.8	3.1	6.8	NA	Validated (3)
Previous day	Birr	1909	December	22	−10.7	5.1 #	−10.4 A	4.9	NA
Flagged				23	4.3	7.5	4.9 B	7.4	NA	Validated (4.3)
Previous day	Botanic Gardens, Glasnevin	1882	December	15	−12.4	5.6	−10.9	3.1	5.7
Flagged				16	4.3	7.9	5.7	7.2	6.7	Validated (4.3)
Previous day	Fitzwilliam Square, Dublin	1882	December	15	−10.4	5.4	−10.4	NA	5.1
Flagged				16	4.4	7.7	5.1	NA	4.8	Validated (4.4)
Previous day	Phoenix Park, Dublin	1882	December	15	−14	5.7	−12.7	3.6	5.4
Flagged				16	4.9	8	5.4	8	6.6	Validated (4.9)

^A Dry-bulb on the previous day at 08:00 (−10.4 °C) and 18:00 (2.1 °C). ^B Dry-bulb on the previous day at 08:00 (4.9 °C) and 18:00 (7.7 °C). # Not thrown back, as read.

and

Table A7. Flagged step-change in daily MAX higher than 4.5 standard deviation of the mean (flag 7) and the dry-bulb thermometer registered on previous and observation days.

Step Change	Station	Year	Month	Day	MIN (°C)	MAX (°C)	Dry-Bulb Previous Day (°C)	Dry-Bulb Morning Obs. Day (°C)	Dry-Bulb Evening Obs. Day (°C)	Decision (°C)
Previous day	Armagh Observatory	1847	December	8	4.1	11.6	1.6	4.4	11.1
Flagged				9	−0.2	18.2	11.1	2.6	2.6	Corrected (11.1)
Previous day		1848	December	5	1.8	5.2	5.4	4.7	2.7
Flagged				6	1.3	17.4	2.7	2.9	1.4	Corrected (5.8)
Previous day		1867	December	1	−2.1	0.4	10.6	8.4	0.1
Flagged				2	−3.2	11.7	0.1	−1.3	−2.2	Corrected (1.1)
Previous day	Birr	1886	December	20	−10.1	−2.8	−1.8 A	−9.9	NA
Flagged				21	−10.4	8.7	−9.9 B	−2.8	NA	Validated (8.7)
Previous day	Killarney	1882	December	14	−11.4	−3.9	−8.6	−10.6	−7.5
Flagged				15	−9.4	9.2	−7.5	4.6	6.1	Validated (9.2)
Previous day	NUI Galway	1926	December	14	0	7.8	6.1	0.6	NA
Flagged				15	−5	−2.2	0.6	−1.7	NA	Corrected (8.9)
Flagged				16	1.7	8.3	−1.7	4.4	NA	Validated (8.3)
Previous day	Phoenix Park, Dublin	1882	December	14	−13.8	−7.6	−7.9	−9.2	−12.7
Flagged				15	−14	5.7	−12.7	3.6	5.4	Validated (5.7)

^A Dry-bulb on the previous day at 08:00 (−1.8 °C) and 18:00 (−6.2 °C). ^B Dry-bulb on the previous day at 08:00 (−9.9 °C) and 18:00 (−6.7 °C).

), and 27,526 for climate persistency (

Table A8. Total of MIN data that failed the quality control test flag 9 and total validated, corrected and deleted data.

Station	Total Data	Total Passed	Total Flagged	Total Validated	Total Corrected	Total Deleted
Armagh Observatory	63,508	63,336	172	161	4	7
Athy	504	496	8	8	0	0
Belfast	306	303	3	3	0	0
Belmullet/Blacksod Point	26,147	24,523	1624	1616	8	0
Birr	41,590	41,065	525	523	1	1
Blackrock	3086	2997	89	89	0	0
Botanic Gardens, Glasnevin	65,273	64,524	1043	1041	2	0
Buncrana	456	437	19	19	0	0
Castletownsend	456	445	11	11	0	0
Commercial Buildings, Dublin	2997	2892	105	105	0	0
Courtown	488	485	3	3	0	0
Donaghadee	457	441	16	13	3	0
Dunmore	367	360	7	7	0	0
Dunsink	275	275	0	0	0	0
Fitzwilliam Square, Dublin	24,379	24,029	350	350	0	0
Glendooen	1528	1469	59	59	0	0
Grafton Street, Dublin	2556	2475	81	81	0	0
Innisgort Island	270	251	19	19	0	0
Kilkenny	542	524	18	18	0	0
Killarney	11,011	10,897	114	114	0	0
Killough	517	510	7	6	1	0
Killybegs	263	260	3	3	0	0
Kilrush	241	223	18	18	0	0
Malin Head	26,131	24,469	1662	1656	6	0
Markree	35,596	35,165	431	428	3	0
NUI Galway	29,029	27,877	1152	1141	8	3
Phoenix Park, Dublin	49,322	48,815	507	507	0	0
Portarlington	4578	4530	48	48	0	0
Portrush	639	592	47	46	1	0
Roches Point	30,991	29,493	1498	1493	5	0
Royal College of Surgeons, Dublin	4349	4331	18	18	0	0
Scattery (Inis Cathaigh)	367	350	17	17	0	0
Valentia Observatory	36,489	35,694	795	793	2	0
Trinity College Dublin	24,896	24,232	664	664	0	0
Total	489,604	478,765	11,133	11,078	44	11

,

Table A9. Total of MAX data that failed the quality control test flag 10 and total validated, corrected and deleted data.

Station	Total Data	Total Passed	Total Flagged	Total Validated	Total Corrected	Total Deleted
Armagh Observatory	63,508	63,308	200	200	0	0
Athy	484	465	19	19	0	0
Belfast	306	303	3	3	0	0
Belmullet/Blacksod Point	26,159	23,903	2256	2232	24	0
Birr	41,586	41,009	577	577	0	0
Blackrock	3086	2951	135	135	0	0
Botanic Gardens, Glasnevin	65,275	64,041	1234	1208	26	0
Buncrana	173	162	11	11	0	0
Castletownsend	457	435	22	22	0	0
Commercial Buildings, Dublin	2999	2876	123	123	0	0
Courtown	488	479	9	9	0	0
Donaghadee	430	430	0	0	0	0
Dunmore	445	436	9	9	0	0
Dunsink	275	272	3	2	1	0
Fitzwilliam Square, Dublin	24,379	23,922	457	457	0	0
Glendooen	0	0	0	0	0	0
Grafton Street, Dublin	2556	2418	138	138	0	0
Innisgort Island	173	156	17	16	1	0
Kilkenny	540	516	24	24	0	0
Killarney	10,839	10,719	120	120	0	0
Killough	517	499	18	18	0	0
Killybegs	264	258	6	6	0	0
Kilrush	238	223	15	15	0	0
Malin Head	26,128	24,512	1616	1615	1	0
Markree	35,606	34,753	853	853	0	0
NUI Galway	29,034	26,968	2066	1992	73	1
Phoenix Park, Dublin	49,377	48,567	810	809	1	0
Portarlington	4577	4478	99	99	0	0
Portrush	639	609	30	30	0	0
Royal College of Surgeons, Dublin	4347	4244	103	103	0	0
Roches Point	31,016	28,783	2233	2231	2	0
Scattery (Inis Cathaigh)	367	358	9	9	0	0
Trinity College Dublin	24,563	23,662	901	898	3	0
Valentia Observatory	36,351	34,890	1461	1455	6	0
Total	487,182	471,605	15,577	15,438	138	1

and

Table A10. Total of MAX and MIN data that failed the quality control test flag 11 and total validated, corrected and deleted data.

Station	Total Data	Total Passed	Total Flagged	Total Validated	Total Corrected	Total Deleted
Armagh Observatory	127,016	127,010	6	6	0	0
Athy	988	988	0	0	0	0
Belfast	612	612	0	0	0	0
Belmullet/Blacksod Point	52,306	52,160	146	145	1	0
Birr	83,176	83,158	18	18	0	0
Blackrock	6172	6166	6	6	0	0
Botanic Gardens, Glasnevin	130,548	130,512	36	36	0	0
Buncrana	629	629	0	0	0	0
Castletownsend	913	907	6	6	0	0
Commercial Buildings, Dublin	5996	5996	0	0	0	0
Courtown	976	976	0	0	0	0
Donaghadee	887	887	0	0	0	0
Dunmore	812	812	0	0	0	0
Dunsink	550	550	0	0	0	0
Fitzwilliam Square, Dublin	48,758	48,752	6	6	0	0
Glendooen	1528	1528	0	0	0	0
Grafton Street, Dublin	5112	5100	12	12	0	0
Innisgort Island	443	443	0	0	0	0
Kilkenny	1082	1082	0	0	0	0
Killarney	21,850	21,838	12	12	0	0
Killough	1034	1034	0	0	0	0
Killybegs	527	527	0	0	0	0
Kilrush	479	479	0	0	0	0
Malin Head	52,259	52,135	124	124	0	0
Markree	71,202	71,184	18	18	0	0
NUI Galway	58,063	57,927	136	133	3	0
Phoenix Park, Dublin	98,699	98,681	18	18	0	0
Portarlington	9155	9155	0	0	0	0
Portrush	1278	1278	0	0	0	0
Roches Point	62,007	61,853	154	154	0	0
Royal College of Surgeons, Dublin	8696	8696	0	0	0	0
Scattery (Inis Cathaigh)	734	734	0	0	0	0
Trinity College Dublin	49,459	49,415	44	44	0	0
Valentia Observatory	72,840	72,766	74	73	1	0
Total	976,786	975,970	816	811	5	0

). Of the flagged values, 98.5% (n = 27,446) were validated, 1.4% (n = 380) corrected, and 0.1% (n = 28) deleted (

Table 5. Total of flagged and percentage of flagged, validated, corrected, and deleted air temperature data per each flag and per decade.

		1830s	1840s	1850s	1860s	1870s	1880s	1890s	1900s	1910s	1920s
Flag no.	1	0	0	0	0	0	3	0	0	0	0
	2	0	1	0	1	1	2	1	0	0	3
	3	0	1	8	0	2	4	0	0	2	0
	4	0	0	4	0	1	2	1	0	0	0
	5	14	14	22	14	24	78	10	2	6	26
	6	0	0	0	0	0	3	0	1	0	0
	7	0	2	0	1	0	3	0	0	0	2
	8	0	0	0	0	0	0	0	0	0	0
	9	42	154	461	271	468	941	1259	1199	1553	1691
	10	39	286	719	304	727	1344	1659	1947	2059	2406
	11	0	18	6	6	44	58	116	106	74	192
Summary	Total flagged	95	476	1220	597	1267	2438	3046	3255	3694	4319
	Total validated	83	460	1189	567	1243	2348	3033	3238	3676	4273
	Total corrected	1	16	31	30	24	84	13	14	18	47
	Total deleted	11	0	0	0	0	6	0	3	0	0
	Total data	5535	33,793	55,509	30,472	50,451	102,410	109,084	106,401	95,240	101,171
	% Flagged	1.7	1.4	2.2	2	2.5	2.4	2.8	3.1	3.9	4.3
	% Validated	87.4	96.6	97.5	95	98.1	96.3	99.6	99.5	99.5	98.9
	% Corrected	1.1	3.4	2.5	5	1.9	3.4	0.4	0.4	0.5	1.1
	% Deleted	11.6	0	0	0	0	0.2	0	0.1	0	0
		1930s	1940s	1950s	1960s	1970s	1980s	1990s	2000s	2010s
Flag no.	1	0	5	0	0	0	0	0	0	0	8	Total
	2	2	1	0	0	0	0	0	0	0	12
	3	2	1	1	1	0	0	0	0	0	22
	4	0	0	1	0	0	0	0	0	0	9
	5	14	2	20	18	0	0	0	0	0	264
	6	0	0	0	0	0	0	0	0	1	5
	7	0	0	0	0	0	0	0	0	0	8
	8	0	0	0	0	0	0	0	0	0	0
	9	1741	878	426	43	0	0	3	0	3	11,133
	10	2296	1173	554	61	0	0	0	3	0	15,577
	11	134	62	0	0	0	0	0	0	0	816
Summary	Total flagged	4189	2122	1002	123	0	0	3	3	4	27,853
	Total validated	4141	2098	979	108	0	0	3	3	4	27,446
	Total corrected	48	24	15	15	0	0	0	0	0	380
	Total deleted	0	0	8	0	0	0	0	0	0	28
	Total data	95,200	82,895	59,693	13,876	7300	7306	7300	7306	5844	976,786
	% Flagged	4.4	2.6	1.7	0.9	0	0	0	0	0.1	2.9	Percentage
	% Validated	98.9	98.9	97.7	87.8	0	0	100	100	100	98.5
	% Corrected	1.1	1.1	1.5	12.2	0	0	0	0	0	1.4
	% Deleted	0	0	0.8	0	0	0	0	0	0	0.1

). The highest number of flagged data concerned the persistency tests: flag 10 (n = 15,577), flag 9 (n = 11,133), and flag 11 (n = 816) (

Table 6. Geographical distribution of flags.

	Flags No.
Series	1	2	3	4	5	6	7	8	9	10	11	Total Flagged	Total Data
Armagh Observatory	1	0	4	0	2	1	3	0	172	200	6	389	127,016
Athy	0	0	0	0	0	0	0	0	8	19	0	27	988
Belfast	0	0	0	0	0	0	0	0	3	3	0	6	612
Belmullet/Blacksod Point	0	0	1	0	46	0	0	0	1624	2256	146	4073	52,306
Birr	0	0	0	0	16	1	1	0	525	577	18	1138	83,176
Blackrock	0	0	0	2	2	0	0	0	89	135	6	234	6172
Botanic Gardens, Glasnevin	0	5	7	0	56	1	0	0	1043	1234	36	2382	130,548
Buncrana	0	0	0	0	0	0	0	0	19	11	0	30	629
Castletownsend	0	0	0	0	0	0	0	0	11	22	6	39	913
Commercial Buildings Dublin	0	0	0	0	4	0	0	0	105	123	0	232	5996
Courtown	0	0	1	0	0	0	0	0	3	9	0	13	976
Donaghadee	0	0	0	0	0	0	0	0	16	0	0	16	887
Dunmore	0	0	0	1	0	0	0	0	7	9	0	17	812
Dunsink	0	0	0	0	0	0	0	0	0	3	0	3	550
Fitzwilliam Square, Dublin	0	1	0	0	0	1	0	0	350	457	6	815	48,758
Glendooen	0	0	0	0	0	0	0	0	59	0	0	59	1528
Grafton Street, Dublin	0	0	1	0	4	0	0	0	81	138	12	236	5112
Innisgort Island	0	0	0	0	0	0	0	0	19	17	0	36	443
Kilkenny	0	0	0	0	0	0	0	0	18	24	0	42	1082
Killarney	3	0	0	0	6	0	1	0	114	120	12	256	21,850
Killough	0	0	0	0	0	0	0	0	7	18	0	25	1034
Killybegs	0	0	0	0	0	0	0	0	3	6	0	9	527
Kilrush	0	0	0	0	0	0	0	0	18	15	0	33	479
Malin Head	0	0	1	0	8	0	0	0	1662	1616	124	3411	52,259
Markree	4	0	0	2	18	0	0	0	431	853	18	1326	71,202
NUI Galway	0	4	4	1	42	0	2	0	1152	2066	136	3407	58,063
Phoenix Park, Dublin	0	0	3	2	24	1	1	0	507	810	18	1366	98,699
Portarlington	0	1	0	0	6	0	0	0	48	99	0	154	9155
Portrush	0	0	0	0	0	0	0	0	47	30	0	77	1278
Roches Point	0	0	0	0	10	0	0	0	1498	103	154	1765	62,007
Royal College of Surgeons, Dublin	0	0	0	1	2	0	0	0	18	2233	0	2254	8696
Scattery (Inis Cathaigh)	0	0	0	0	0	0	0	0	17	9	0	26	734
Trinity College Dublin	0	0	0	0	4	0	0	0	664	1461	74	2203	49,459
Valentia Observatory	0	1	0	0	14	0	0	0	795	901	44	1755	72,840
Total	8	12	22	9	264	5	8	0	11,133	15,577	816	27,854	976,786

). The greatest number of corrections were made on flagged data that failed the quality control test flag 5 (n = 170) (Table A5), flag 10 (n = 138) (Table A9), and flag 9 (n = 44) (Table A8). More issues were identified in the flagged MAX, resulting in a greater number of corrections and deletions than the MIN. Concerning the temporal distribution of flagged data, more flags were registered in the 1920s (n = 4320), 1930s (n = 4189), and 1910s (n = 3694) (Table 5). The highest number of flags were registered at Belmullet/Blacksod Point (n = 4073), Malin Head (n = 3411), and NUI Galway (n = 3407) (Table 6).

3.2. Homogenisation

All series were inhomogeneous before homogenisation testing (

Table 7. Average test statistics for series included in the national network. Critical value (significance level 0.05): 21.94. TSb—test statistics before homogenisation; TSa—test statistics after homogenisation; RC of TS—relative change of TS; RM—relative modification; SE—statistics for estimated inhomogeneities.

Series	MAX Series					MIN Series
	TSb	TSa	RC of TS	RM	SE	TSb	TSa	RC of TS	RM	SE
Phoenix Park, Dublin	217.89	27.75	0.87	0.13	94.94	897.80	58.15	0.94	0.81	473.55
Botanic Gardens, Glasnevin	705.19	34.11	0.95	0.31	631.39	2970.01	36.10	0.99	1.16	3709.10
Dublin city	973.34	33.17	0.97	0.90	562.09	491.24	25.12	0.95	0.42	700.65
Roches Point	78.36	25.05	0.68	0.42	63.75	168.46	29.33	0.83	0.31	85.17
Malin Head	149.42	23.51	0.84	0.29	91.41	74.40	25.14	0.66	0.27	43.70
Birr/Gurteen	264.54	29.41	0.89	0.68	409.24	596.11	22.26	0.96	0.27	238.60
NUI Galway/ Athenry	1525.84	22.04	0.99	1.07	1641.70	2080.64	21.65	0.99	1.15	1976.95
Valentia Observatory	111.04	33.04	0.70	0.39	42.49	330.28	25.01	0.92	0.41	87.28
Markree	546.91	54.76	0.90	0.83	455.06	1114.49	21.63	0.98	0.41	443.83
Armagh Observatory	203.09	18.42	0.91	0.39	78.63	174.54	25.87	0.85	0.19	125.59
Blacksod Point/Belmullet	466.70	41.61	0.91	0.35	268.52	513.83	45.58	0.91	0.61	356.02
Average (National network)	476.57	31.17	0.93	0.52	394.47	855.62	30.53	0.96	0.55	749.13

and

Table 8. Average test statistics for series included in the Dublin/Midlands and Western networks. Critical value (significance level 0.05): 21.94. TSb—test statistics before homogenisation; TSa—test statistics after homogenisation; RC of TS—relative change of TS; RM—relative modification; SE—statistics for estimated inhomogeneities.

Series	MAX Series					MIN Series
	TSb	TSa	RC of TS	RM	SE	TSb	Tsa	RC of TS	RM	SE
Phoenix Park, Dublin	211.78	23.68	0.89	0.11	54.17	949.50	82.27	0.91	0.61	455.30
Botanic Gardens, Glasnevin	701.87	31.15	0.96	0.26	490.53	2045.17	53.17	0.97	1.06	1804.43
Dublin city	917.33	25.27	0.97	0.83	549.95	249.52	20.44	0.92	0.26	151.63
Roches Point	92.93	43.87	0.53	0.36	17.40	78.89	42.69	0.46	0.12	13.61
Malin Head	230.26	36.22	0.84	0.35	78.23	169.30	25.96	0.85	0.38	90.11
Birr/ Gurteen	166.76	30.17	0.82	0.50	116.42	170.45	20.66	0.88	0.25	46.94
NUI Galway/ Athenry	1314.64	67.43	0.95	0.90	1216.11	2423.70	36.41	0.98	1.10	2013.58
Valentia Observatory	133.80	22.13	0.83	0.28	52.35	106.31	33.79	0.68	0.13	15.07
Markree	689.60	53.75	0.92	0.59	258.80	197.98	30.80	0.84	0.31	62.81
Armagh Observatory	152.56	25.85	0.83	0.31	38.44	222.45	18.96	0.91	0.33	187.99
Blacksod Point/Belmullet	389.05	23.12	0.94	0.39	248.78	201.20	29.82	0.85	0.35	97.24
Average (Dublin/Midlands network)	430.06	27.22	0.94	0.40	249.90	727.42	39.10	0.95	0.50	529.26
Average (Western Network)	475.05	41.09	0.91	0.48	311.94	529.56	33.25	0.94	0.40	382.07

). The homogenisation procedures applied using MASHv3.03 have reduced the inhomogeneities for all series (Table 7 and Table 8). The verification statistics show that greater inhomogeneities were presented in the MIN series before homogenisation.

For the MAX series in the national network (Table 7), the relative change of TS is highest for the NUI Galway/Athenry series (0.99), which had the highest estimated inhomogeneities (1641.70). This series had the highest TSb (1525.84), which were reduced near to the critical value (21.94) with lower TSa (22.04). The greatest relative changes of TS were registered at Dublin city (0.97) and the Botanic Gardens, Glasnevin (0.95). The lowest relative change of TS (0.68) was reported at Roches Point, which exhibited a low TSb (78.36) before the homogenisation testing. The majority of the series had low TSa with the lowest value at Armagh Observatory (18.42).

For the MIN series in the national network (Table 7), the biggest relative change of TS occurred in the Botanic Gardens and NUI Galway/Athenry (0.99), followed by Markree (0.98). The highest relative inhomogeneities were registered at the Botanic Gardens (3709.10) and NUI Galway/Athenry (1976.95). The homogenisation procedures have improved the homogeneity of these series which register low TSa near the critical value compared to the previous TSb for the Botanic Gardens (36.10) and NUI Galway/Athenry (21.65). The lowest relative change of TS (0.66) was verified at Malin Head, which presented the lowest TSb (74.40). Overall, the series register low TSa, although Phoenix Park, Dublin (58.15) and Blacksod Point/Belmullet (45.58) could not be diminished near the critical value (21.94).

The MAX series in the Dublin/Midlands network (Table 8) exhibited similar TSa in the Phoenix Park, Botanic Gardens, Dublin city, Birr/Gurteen, and Armagh Observatory series when compared to the results obtained in the national network. However, NUI Galway/Athenry (TSa 67.43 vs. 22.04), Roches Point (TSa 43.87 vs. 25.05), and Malin Head (TSa 36.22 vs. 23.51) series registered worse TSa when homogenised with fewer reference series in the Western regional network of stations in comparison to the TSa results obtained in the national network. However, the Valentia Observatory series improved near the level of the critical value (Table 8).

The MIN series in the Dublin/Midlands network (Table 8) showed similar TSa results in the Dublin city, Birr/Gurteen, and Armagh Observatory series, whereas the Phoenix Park, Dublin (TSa 82.27 vs. 58.15) and the Botanic Gardens (TSa 53.17 vs. 36.10) series presented more inhomogeneities when compared to the outcomes derived from the application of more reference series within the national network. Roches Point (TSa 42.69 vs. 29.33) and NUI Galway/Athenry (TSa 36.41 vs. 21.65), when included in the Western regional network, have more inhomogeneities in comparison to the final results derived from the application of more reference series in the national network.

Estimated break-points of ±0.2 °C in the annual MAX and MIN series were cross-referenced with station metadata. A total of 27 break-points were estimated in the MAX series within the national network. NUI Galway/Athenry (n = 9, 33.3%) presented a greater frequency of break-points, although no station metadata were available for 77.8% (n = 7) of the estimated break-points. The NUI Galway/Athenry series contains more estimated break-points in the late 19th and early 20th centuries, and in the 1930s. The documented break-points in MAX in the national network (44.4%) are related to possible changes in thermometers (2.7%), conversion to automatic station (2.7%), screen (3.7%), relocation (22.2%) and observation time (3.7%). A total of 54 break-points were estimated in the MIN series within the national network. The NUI Galway/Athenry series contained the greatest frequency of break-points (n = 20; 36.4%), followed by the Belmullet series (n = 12; 21.8%). The greatest estimated shifts are in the NUI Galway/Athenry series, although no metadata is available for 90% (n = 18) of the estimated break-points. The highest shift in NUI Galway/Athenry occurred in 1931 (–2.27 °C), although this is not documented by metadata. The station metadata explains 33.3% of the estimated break-points in the MIN in the national network, which are associated with likely changes in exposure (1.9%), thermometers (14.8%), observers (5.6%), relocation (9.3%), and observation time (1.9%).

A total of 26 break-points were estimated in the MAX series in the regional networks. Fewer estimated break-points were registered in the Dublin city series compared to the results verified in the national network (n = 5 versus n = 7). The break-point associated with relocation from Valentia Island to Caherciveen in 1892 was apparent in the Western network homogenisation (+0.20 °C). A greater number of break-points were present in the NUI Galway/Athenry series (n = 10, 38.5%). The station metadata explains 38.5% of the estimated break-points, which are likely to be linked with changes of location (19.2%), thermometers or thermometers’ errors (11.5%), observation time (3.8%), or conversion to automatic station (3.8%) for MAX in regional networks.

A total of 60 break-points were estimated in the MIN series in the regional networks. More estimated break-points were detected in the Phoenix Park, Malin Head, and NUI Galway/Athenry series as part of regional networks. A greater number of break-points were found in the NUI Galway/Athenry series (n = 22, 36.7%). For the Blacksod Point/Belmullet series, a greater number of break-points explained by metadata are estimated in the national network (n = 8) compared with the Western network (n = 1) homogenisation procedures. The greatest estimated break-point (–2.20 °C in 1931) is present in the NUI Galway/Athenry series, although no station metadata is available. The metadata describe 31.7% of the estimated break-points, which are related to possible changes of the observer (6.7%), location (11.7%), conversion to automatic station (3.3%), thermometers (8.3%), and screen painting (1.7%) for MIN in regional networks.

4. Discussion

4.1. Quality Control

The manual assessment of flagged data and cross-reference with detailed station metadata and sources on past extreme air temperature events were crucial in analysing flagged data for climate consistency. References to extreme air temperature events were available for 41.2% of the flagged data for climate consistency. Examples include the cold wave of April 1917, e.g., [42], and the heat wave of July 1876, e.g., [43].

A greater number of climate persistency flags were registered at Malin Head, Belmullet/Blacksod Point, and NUI Galway, which can be explained by their proximity to the Atlantic Ocean, which may be responsible for subdued air temperature ranges, and the registry of data as whole degrees Fahrenheit instead of to one decimal place. The greater number of flagged data in the 1910s to the 1930s may be associated with the predominant registry of readings as whole degrees Fahrenheit during this time.

More observations were flagged for internal consistency in the NUI Galway (n = 42) and Botanic Gardens (n = 56) series. The observations for these stations were taken under a voluntary role during the 19th century, possibly explaining the high number of flagged data. Additionally, the handwritten registers used to rescue the historical series at NUI Galway (1885–1952) and the Botanic Gardens (1885–1910) are not kept in the archives of Met Éireann and thus do not comprise red ink corrections made as part of manual quality control [2]. Errors referred to inconsistencies of MAX and MIN data with the dry-bulb on the previous and observation days, reversed values, gross errors, internal consistency, or the interpolation of missing data.

Long-term historical dry-bulb air temperature readings are presently not available in a digital format, and thus all flagged MAX and MIN data were manually cross-referenced with dry-bulb records. The inclusion of dry-bulb records in the R script to check the consistency of MAX and MIN data would avoid higher rates of false-positive flagged data. Thus, future work should involve the digitisation of historical dry-bulb records [1]. Additional historical MAX and MIN series [1] should also be rescued to create a denser station network with which to apply a spatial quality control test [24]. The rescue of the historical MAX and MIN series would allow the quality control of records dating back to the 18th century [1]. Although not digitised at present, historical thermographs register air temperature in a 24 h period, indicating the MIN and MAX records that could be used for cross-reference of flagged data [27] in future work.

4.2. Homogenisation

The raw and homogenised series as part of national and regional networks were correlated to the long-term Central England air temperature series [41] for 1885–2018 (

Table A11. Pearson correlations between the Central England series [41] and the raw and homogenised MAX series in 1885–2018. All correlations are significant at the 0.01 level. Series: (1) Phoenix Park Dublin, (2) Botanic Gardens, Glasnevin, (3) Dublin city, (4) Roches Point, (5) Malin Head, (6) Birr/Gurteen, (7) NUI Galway/Athenry, (8) Valentia Observatory, (9) Markree, (10) Armagh Observatory, (11) Blacksod Point/Belmullet.

	1	2	3	4	5	6	7	8	9	10	11
Annual (raw)	0.933	0.907	0.821	0.809	0.881	0.861	0.532	0.807	0.792	0.90	0.851
Annual (national homogenisation)	0.946	0.936	0.945	0.867	0.900	0.908	0.874	0.854	0.888	0.918	0.861
Annual (regional homogenisation)	0.939	0.941	0.943	0.850	0.902	0.912	0.865	0.852	0.893	0.922	0.862
Winter (raw)	0.711	0.700	0.717	0.660	0.665	0.671	0.531	0.662	0.631	0.678	0.605
Winter (national homogenisation)	0.721	0.719	0.723	0.689	0.665	0.693	0.650	0.667	0.660	0.678	0.632
Winter (regional homogenisation)	0.717	0.716	0.713	0.683	0.655	0.698	0.655	0.673	0.651	0.688	0.629
Spring (raw)	0.936	0.932	0.854	0.829	0.898	0.871	0.769	0.800	0.850	0.901	0.835
Spring (national homogenisation)	0.936	0.919	0.922	0.860	0.905	0.893	0.853	0.823	0.877	0.902	0.848
Spring (regional homogenisation)	0.930	0.914	0.908	0.860	0.900	0.900	0.850	0.830	0.882	0.908	0.847
Summer (raw)	0.925	0.904	0.840	0.808	0.852	0.879	0.647	0.792	0.844	0.898	0.798
Summer (national homogenisation)	0.939	0.923	0.920	0.814	0.853	0.905	0.839	0.836	0.877	0.910	0.806
Summer (regional homogenisation)	0.936	0.919	0.924	0.796	0.859	0.909	0.826	0.815	0.870	0.908	0.801
Autumn (raw)	0.915	0.885	0.873	0.778	0.889	0.861	0.627	0.784	0.785	0.896	0.808
Autumn (national homogenisation)	0.920	0.916	0.927	0.852	0.886	0.892	0.844	0.796	0.861	0.901	0.785
Autumn (regional homogenisation)	0.921	0.921	0.931	0.838	0.883	0.881	0.813	0.796	0.846	0.905	0.798

and

Table A12. Pearson correlations between the Central England series [41] and the raw and homogenised MIN series in 1885–2018. All correlations are significant at the 0.01 level. Series: (1) Phoenix Park Dublin, (2) Botanic Gardens, Glasnevin, (3) Dublin city, (4) Roches Point, (5) Malin Head, (6) Birr/Gurteen, (7) NUI Galway/Athenry, (8) Valentia Observatory, (9) Markree, (10) Armagh Observatory, (11) Blacksod Point/Belmullet.

	1	2	3	4	5	6	7	8	9	10	11
Annual (raw)	0.822	0.785	0.803	0.807	0.741	0.803	0.326	0.773	0.695	0.865	0.593
Annual (national homogenisation)	0.866	0.877	0.869	0.827	0.800	0.848	0.831	0.822	0.838	0.863	0.804
Annual (regional homogenisation)	0.844	0.847	0.846	0.814	0.756	0.810	0.754	0.778	0.770	0.841	0.725
Winter (raw)	0.636	0.630	0.625	0.564	0.573	0.616	0.339	0.561	0.582	0.628	0.480
Winter (national homogenisation)	0.641	0.666	0.654	0.587	0.580	0.618	0.582	0.565	0.620	0.626	0.566
Winter (regional homogenisation)	0.648	0.665	0.649	0.672	0.630	0.614	0.655	0.637	0.657	0.623	0.618
Spring (raw)	0.846	0.806	0.799	0.788	0.739	0.825	0.559	0.757	0.787	0.876	0.666
Spring (national homogenisation)	0.888	0.897	0.856	0.812	0.786	0.850	0.821	0.785	0.831	0.871	0.770
Spring (regional homogenisation)	0.854	0.874	0.838	0.796	0.746	0.823	0.751	0.757	0.799	0.869	0.692
Summer (raw)	0.820	0.709	0.803	0.792	0.724	0.764	0.511	0.715	0.751	0.845	0.635
Summer (national homogenisation)	0.842	0.845	0.837	0.804	0.802	0.801	0.796	0.782	0.801	0.850	0.762
Summer (regional homogenisation)	0.819	0.822	0.828	0.764	0.721	0.771	0.774	0.706	0.724	0.823	0.719
Autumn (raw)	0.849	0.808	0.854	0.758	0.743	0.800	0.539	0.751	0.698	0.834	0.657
Autumn (national homogenisation)	0.846	0.845	0.856	0.789	0.760	0.799	0.797	0.764	0.780	0.829	0.755
Autumn (regional homogenisation)	0.852	0.845	0.853	0.776	0.723	0.813	0.775	0.765	0.767	0.833	0.737

). The homogenisation improved the positive Pearson correlations for all stations in the MAX series (Table A11). The NUI Galway/Athenry series, which exhibited the lowest correlation among the raw series (r = 0.532), improved when homogenised as part of national (r = 0.874) and regional (r = 0.865) networks. In the MIN series, all stations presented positive correlations that were improved with the homogenisation (Table A12). Greater correlations were assessed in the MAX series. The raw NUI Galway/Athenry series had the lowest correlation among the Irish stations (r = 0.326). The homogenisation of the NUI Galway/Athenry series as part of national (r = 0.831) and regional (r = 0.754) networks improved the quality of the series.

A few relocations of stations were better assessed in the estimated break-points in the series homogenised within a regional network. For example, the Dublin city series have a relocation of the station from Fitzwilliam Square to Trinity College Dublin in 1904, representing a bias of −0.27 °C. A break-point of 0.28°C was identified in 1904 when the series were homogenised as part of the Dublin/Midlands network. In comparison, a small inhomogeneity (−0.02 °C) was identified in 1904 when the Dublin series were homogenised as part of the national network, highlighting that the homogenisation of these series within the regional network is more robust to estimate the relocation signal. This was also the case with an inhomogeneity associated with a station relocation in 1948 at Blacksod Point which was better assessed in the MIN homogenised as part of the Western network.

The number of frost days was reduced in the homogenised data (with gaps) at Phoenix Park, Botanic Gardens, Dublin city, Malin Head, and Valentia Observatory. However, the homogenised data as part of a regional network preserves a greater number of frost days in comparison to the series homogenised as part of the national network. The greatest reduction of the number of frost days is displayed in the homogenised Botanic Gardens series: −1219 days (regional network) and −1342 (national network). Except for the Glasnevin series, the homogenised series, as part of a regional network, preserve a greater number of summer days compared to the series homogenised in a national network.

For the reasons highlighted above, the homogenised series in the Dublin/Midlands and Western regional networks were chosen to assess extreme air temperature indices [4,5,6] rather than the series homogenised as part of the national network (Figure 3, Figure 4, Figure 5 and Figure 6).

Despite high correlations among all stations for the MAX and MIN series, because the national network attempts to include both coastal and inland stations, the stations are in different climatic regions and have different controls, such as orography or distance to the ocean. The historical network of stations is scarce, limiting the inclusion of more reference series in the same climatic region as part of regional networks. Although it is a coastal station, Markree presents characteristics of an inland station due to its sheltered relief conditions [19], which can decrease the winter MIN of Malin Head (a coastal station in a northerly location) since both stations are part of the Western network.

The historical MIN series at NUI Galway/Athenry and the Botanic Gardens, Glasnevin should be analysed with caution (Figure 5 and Figure 6). In the case of the NUI Galway/Athenry series, the historical observations were made at NUI Galway under a voluntary role, and the station was not included in the official networks of telegraphic weather reporting or second order stations under the direction of the Meteorological Office and later by Met Éireann [4]. Additionally, scarce inspections and metadata are available. Except for an inspection of the station taken in 1884, no other inspections are available in the Quarterly Journal of the Royal Meteorological Society, the Report of the Meteorological Council to the Royal Society, or the Report of the Meteorological Council, despite the existence of several inspections in other stations in western Ireland [2]. It is therefore possible that inspections were not made, obsolete instrumentation was not replaced, or instrumental and observational errors were not identified and corrected. In the modern series, no metadata are accessible on the maintenance of green areas, such as the planting, growing, or cutting of trees, for cross-reference with estimated break-points. New buildings were added in NUI Galway throughout the time, which could also explain break-points. Several relocations occurred; in 2002, the thermometer screen was re-located due to security reasons [44], indicating that the instruments were perhaps compromised.

Concerning the Botanic Gardens, Glasnevin series (Figure 5 and Figure 6), the station metadata report that the thermometers were periodically stolen, broken, or interfered with or vandalised by intruders, resulting in relocations of the thermometer screen and replacement of instrumentation [2], which may have had an impact on the MIN.

The historical station network is scarce, which constitutes an obstacle to perform homogeneity testing on dense regional networks. Despite the existence of 89 inventoried historical MAX and MIN series registered pre-1900, the majority of the records are only available as paper data-sources, or the daily resolution of the records is at present missing [1]. The oldest MAX and MIN records date back to the period 1787–1788 [1]. Station metadata on observation practices and instrumentation is scarce or currently not available, which does not allow quality control and homogenisation in combination with statistical procedures of early instrumental records. Also, the majority of the historical MAX and MIN records are short-term series registered throughout the time in diverse geographical areas [1], which compromises the merging of series in order to create long-term records.

5. Conclusions

For the first time, a long-term network of daily MAX and MIN series has been quality-controlled and homogenised in the period 1885–2018, which will fill critical gaps in climate research in Ireland. The quality-controlled and homogenised MAX and MIN series as part of regional networks that were produced in this research will be employed to calculate trends and assess the frequency, duration, intensity, and distribution of extreme air temperature indices recommended by the ETCCDI, as well as heat waves and cold waves dating back to the 19th century [4,5,6]. Previous research on past extreme air temperature indices in Ireland has focused on the instrumental period with available digital MAX and MIN data, generally from the 1940s and 1950s onwards [45].

The Island of Ireland has a great heritage of historical meteorological observations that remain in paper data-sources across multiple archives [1]. A total of 86 records kept during the 19th century and three records registered during the 18th century, which contain MAX and MIN data, have been inventoried and it is possible that other records might be found [1]. Future work should aim to rescue historical MAX and MIN records, especially pre-1885, in order to digitise additional long-term series and merge short-term series to extend the temporal and geographical distribution of long-term temperature records, and to create a denser network of stations to apply quality control and homogenisation procedures. Further efforts should be made to rescue additional historical station metadata for cross-reference with homogenisation procedures.