Trends in reconstructed monthly, seasonal and annual flows for Irish catchments (1900–2016)
2022; Wiley; Volume: 78; Issue: 9 Linguagem: Inglês
10.1002/wea.4288
ISSN1477-8696
AutoresPaul O’Connor, Hadush Meresa, Conor Murphy,
Tópico(s)Hydrology and Drought Analysis
ResumoWeatherEarly View Short ArticleOpen Access Trends in reconstructed monthly, seasonal and annual flows for Irish catchments (1900–2016) Paul O'Connor, Corresponding Author Paul O'Connor [email protected] orcid.org/0000-0002-7755-0831 Irish Climate Analysis and Research Units (ICARUS), Department of Geography, Maynooth University, County Kildare, Ireland Correspondence to: P. O'Connor [email protected]Search for more papers by this authorHadush Meresa, Hadush Meresa Irish Climate Analysis and Research Units (ICARUS), Department of Geography, Maynooth University, County Kildare, IrelandSearch for more papers by this authorConor Murphy, Conor Murphy orcid.org/0000-0003-4891-2650 Irish Climate Analysis and Research Units (ICARUS), Department of Geography, Maynooth University, County Kildare, IrelandSearch for more papers by this author Paul O'Connor, Corresponding Author Paul O'Connor [email protected] orcid.org/0000-0002-7755-0831 Irish Climate Analysis and Research Units (ICARUS), Department of Geography, Maynooth University, County Kildare, Ireland Correspondence to: P. O'Connor [email protected]Search for more papers by this authorHadush Meresa, Hadush Meresa Irish Climate Analysis and Research Units (ICARUS), Department of Geography, Maynooth University, County Kildare, IrelandSearch for more papers by this authorConor Murphy, Conor Murphy orcid.org/0000-0003-4891-2650 Irish Climate Analysis and Research Units (ICARUS), Department of Geography, Maynooth University, County Kildare, IrelandSearch for more papers by this author First published: 29 August 2022 https://doi.org/10.1002/wea.4288AboutSectionsPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinkedInRedditWechat Graphical Abstract Trends in annual, seasonal and monthly reconstructed mean flows for 51 Irish catchments are evaluated for the period 1900–2016. Annually, significant increasing trends are identified for western catchments. In winter, significant increasing trends dominate the western seaboard, with decreasing trends in the southeast. Few significant trends are found in spring and summer, while autumn shows significant increasing trends in northern catchments. Months with the largest number of significant increasing trends are January, November and December. Trend persistence was evaluated by dropping the start year of analysis, with winter showing the most persistent trends across the record. Introduction Analysis of trends in historical river flows furthers understanding of variability and change for water management. In the United Kingdom (UK), Harrigan et al. (2018) examined trends in river flows finding increasing trends in autumn and winter, decreases in spring and contrasting northwest/southeast increasing/decreasing patterns in summer. In Ireland, Murphy et al. (2013) assessed trends in observed flows for 43 Irish catchments over the period 1976–2009, identifying decreasing trends in winter and spring flows and increasing trends in summer. However, such analyses can be hampered by short record lengths (e.g. Wilby, 2006; Slater et al., 2021). In Europe, which has amongst the longest and most spatially dense flow records (Brönnimann et al., 2019), average record length is 54 years (Mangini et al., 2018). In Ireland, flow records typically commenced in the 1970s in response to severe drought at the time (Murphy et al., 2013), with only a handful of gauges extending to earlier periods. Consequently, researchers have attempted to reconstruct flows to extend observed records and improve understanding of variability and change (e.g. Jones et al., 2006; Spraggs et al., 2015; Brigode et al., 2016; Smith et al., 2019). Here, we employ monthly flow reconstructions developed by O'Connor et al. (2021) for Irish catchments to assess trends in annual, seasonal and monthly mean flows and examine the sensitivity of trends to the period of record analysed. Data and methods Study catchments and flow data Trends in flow reconstructions were found for 51 catchments across Ireland (see Table 1 for details of the flow stations and related catchment meteorological and hydrometric data). For a full background on how the monthly flows were reconstructed, see O'Connor et al. (2021). In brief, catchment precipitation and evapotranspiration were derived by bias correcting Casty et al.'s (2007) gridded (0.5°× 0.5°) precipitation and temperature datasets and used as inputs to a conceptual rainfall–runoff model and artificial neural network to simulate monthly flows for the past 250 years for each catchment. The median simulation from across hydrological modelling approaches is employed here. Given large uncertainties in pre-1900 reconstructions, only data from 1900 to 2016 were used, with the choice of end year (i.e. 2016) determined by the availability of concurrent hydrological and meteorological data. Annual, seasonal (winter (DJF), spring (MAM), summer (JJA), and autumn (SON)) and monthly mean flow indices were extracted for all 51 catchments. Table 1. Details of the 51 study catchments. As well as overall flow station data, catchment area (km2), Standard period Average Annual Rainfall (SAAR) and annual runoff (mm) are displayed. Rows are ordered by SAAR values from lowest (blue) to highest (red) with similar colouring applied to annual runoff to allow for visual comparisons between values. River flow station ID Station Waterbody Latitude (°) Longitude (°) Area (km2) SAAR (mm) Annual runoff (mm) 14019 Levitstown Barrow 52.94 −6.95 1697 839.18 392.85 7009 Navan Weir Boyne II 53.64 −6.67 1658 868.88 467.32 14007 Derrybrock Stradbally 53.04 −7.09 115 869.39 511.51 6013 Charleville Dee 53.86 −6.41 309 879.51 424.77 7012 Slane Castle Boyne I 53.71 −6.56 2408 888.15 505.77 15005 Durrow Ft. Br. Erkina 52.85 −7.40 379 889.40 477.33 25006 Ferbane Brosna 53.27 −7.83 1163 898.01 465.74 6014 Tallanstown Glyde 53.92 −6.55 270 913.06 508.42 26021 Ballymahon Inny 53.56 −7.76 1099 942.42 545.98 24008 Castleroberts Maigue 52.54 −8.77 806 948.22 498.14 15006 Brownsbarn Nore I 52.50 −7.09 2418 950.18 513.76 15001 Annamult Kings 52.55 −7.20 445 954.65 485.02 25034 Rochfort L. Ennell Trib 53.47 −7.37 11 958.18 622.62 16010 Anner Anner 52.38 −7.63 437 961.37 461.52 26058 Ballyrink Br. Inny Upper 53.78 −7.25 60 971.33 609.28 36019 Belturbet Erne 54.10 −7.45 1492 991.17 588.79 15003 Dinin Bridge Dinin 52.72 −7.29 299 991.95 609.81 16008 New Bridge Suir II 52.46 −8.00 1090 1001.64 662.97 36015 Anlore Finn 54.18 −7.18 153 1009.16 689.58 24030 Danganbeg Deel 52.41 −9.00 259 1013.26 537.15 16009 Caher Park Suir I 52.36 −7.92 1583 1047.05 623.79 3051 Faulkland Blackwater (Mon) 54.28 −6.92 143 1048.85 652.97 12001 Scarrawalsh Slaney 52.55 −6.55 1031 1067.64 609.18 16011 Clonmel Suir III 52.35 −7.69 2144 1072.13 713.24 15007 Kilbricken Nore II 52.96 −7.46 340 1078.03 699.69 30007 Ballygaddy Clare 53.53 −8.87 470 1096.77 713.12 6030 Ballygoly Big 54.03 −6.24 10 1106.36 855.20 25001 Annacotty Mulkear 52.67 −8.53 648 1138.26 749.58 25030 Scarriff Graney 52.91 −8.53 279 1182.74 914.50 19001 Ballea Owenboy 51.82 −8.42 103 1198.63 727.18 35005 Ballysadare Ballysadare 54.21 −8.51 640 1211.79 848.16 18002 Ballyduff Blackwater I 52.13 −8.69 2334 1212.61 792.55 16012 Tar Bridge Tar 52.27 −7.84 230 1222.04 932.94 25002 Barrington S Br. Newport (Munster) 52.64 −8.48 230 1228.72 822.23 27002 Ballycorey Fergus 52.87 −8.97 511 1261.91 654.84 18003 Killavullen Blackwater II 52.14 −8.05 1257 1287.50 871.17 34001 Rahans Moy 54.10 −9.16 1975 1289.56 883.07 16013 Fourmilewater Nire 52.27 −7.76 94 1303.17 1186.93 18006 Cset Mallow Blackwater IV 52.10 −9.10 1052 1311.25 959.78 23002 Listowel Feale 52.44 −9.48 647 1387.79 1089.43 39006 Lennan Claragh 55.03 −7.68 245 1434.82 1094.59 35002 Billa Bridge Owenbeg 54.18 −8.55 81 1458.15 1317.75 39009 Aghawoney Fern O/L 55.04 −7.72 207 1485.30 1248.38 33001 Glenamoy Glenamoy 54.24 −9.70 76 1509.06 1185.21 18050 Duarrigle Blackwater III 52.15 −8.52 250 1511.34 1059.69 26029 Dowra Shannon 54.19 −8.02 117 1545.73 1307.47 32012 Newport Weir Newport 53.89 −9.52 146 1651.97 1268.71 22006 Flesk Flesk (Laune) 52.05 −9.50 329 1741.05 1386.70 38001 Clonconwal Ownea 54.78 −8.37 111 1795.14 1534.65 22035 Laune Bridge Laune 52.06 −9.62 560 1858.03 1584.36 21002 Coomhola Coomhola 51.74 −9.45 65 2157.84 1992.39 Trend analysis Trends are assessed using a modified version of the non-parametric Mann–Kendall (MK) test that accounts for autocorrelation (Yue and Wang, 2004), with the threshold for significance set at the 0.05 level. The non-parametric Theil–Sen's slope (Theil, 1950; Sen, 1968) estimator was also derived to evaluate the magnitude of trends. Trends were evaluated in two ways. First, we use a fixed period of analysis (1900–2016) to examine trends over the full period. Slope magnitudes and directions for each catchment, at annual, seasonal and monthly timescales were calculated and mapped to identify regional patterns. Second, we examine the persistence of trends, or their dependency on the period of record analysed, by sequentially dropping the start year of analysis, to a minimum record length of 16 years, which provided a sufficient length of time to identify an accurate trend in the data whilst allowing all twentieth century values to be contained within the analysis. For each catchment and indicator, the resultant series of MK Z values were plotted and examined. Results Annual and seasonal trends Figure 1 plots trend magnitude and significance for annual mean flows for the full period of record. Increasing trends predominate, with the exception of catchments in the southeast. Large and significant increasing trends are found for western, northern and southwestern catchments. By examining trend persistence (Figure 2), it is apparent that such large increasing trends are only evident for long records. For tests commencing post 1970, few significant trends are evident. Figure 1Open in figure viewerPowerPoint Theil–Sen slope estimates for mean annual flows for the 51 study catchments for the period 1900–2016. Trend directions are indicated by arrowhead direction and colour, with arrowhead size representative of slope magnitude. Significant trends, at the 0.05 level, are indicated using white triangles. Figure 2Open in figure viewerPowerPoint Persistence of trends (sequentially varying start year of Mann–Kendall tests) for annual mean flows. Grey lines represent MK Z scores for each of the 51 study catchments. Trends for median flow values (black) across all 51 catchments are also displayed. Dashed red lines at +1.96/−1.96 represent thresholds above/below which trends are significant at the 0.05 level. Seasonal trends for the full period are plotted in Figure 3. For winter, significant increasing trends are found for catchments in the northwest and along the Atlantic seaboard. Large increasing trends are also evident in the southwest but not significant at the 0.05 level. In the east and southeast decreasing trends in winter mean flows are evident, some of which are significant. For winter, in catchments showing increasing trends, these are relatively consistent irrespective of the period of record analysed (Figure 4), however significant increasing trends are more common in longer records. While trend tests commencing from the 1970s onwards generally show increases, they tend to be weaker and non-significant compared to those found in longer records. Figure 3Open in figure viewerPowerPoint As per Figure 1 but for seasonal mean flows. Figure 4Open in figure viewerPowerPoint As per Figure 2 but for seasonal mean flows. Spring is marked by an absence of significant trends for the fixed period 1900–2016. Broadly speaking, the western half of the country tends to show increasing trends, largest in the northwest, while the eastern half of the country shows weak decreasing trends. However, trends in spring mean flows (Figure 4) are highly sensitive to the period of record analysed. Tests commencing in the 1920s and 1930s show large and significant increasing trends for many catchments. Conversely, tests commencing in the mid-1970s show widespread decreasing trends, often significant, across catchments. Like spring, summer shows a marked absence of significant trends for the 1900–2016 fixed period (Figure 3). Most catchments show weak (non-significant) decreasing trends, with some catchments in the upper Shannon basin showing weak (non-significant) increasing trends. Even the direction of trends in summer mean flows is dependent on the period of record analysed (Figure 4). Tests commencing prior to 1920 show a predominance of decreasing, non-significant trends. Tests commencing after ~1970, the period concurrent with available observed records, tend to show increasing trends in summer mean flows across most catchments. In autumn, large and significant increasing trends are found for catchments in the northwest and north and for some catchments in the southwest for the fixed period 1900–2016. The remainder of catchments tends to show weak (non-significant) increasing trends, with the exception of catchments in the southeast where weak (non-significant) decreasing trends are apparent. Trends in autumn flows are, in general, of a consistent direction for test start years commencing prior to the 1970s. For tests commencing after the 1970s, there is a greater tendency towards negative trends, with many catchments showing significantly decreasing trends for tests commencing post 1995. Monthly trends Trends in monthly flows for the fixed period 1900–2016 are presented in Figure 5. For winter months, December shows significant increasing trends in northwestern catchments. The number and spatial extent of significant increasing trends increases in January with catchments across the north, northwest and along a considerable portion of the west coast all showing significant (increasing) trends. Large increasing trends are also evident in February but are not significant. In each winter month, catchments in the east and southeast show non-significant decreasing trends. For spring months, March shows the largest trends, with increases in the west and decreases in the east, however only two catchments (north and northwest) show significant increasing trends. For April and May, trends are weak and non-significant, with no clear spatial patterns. For summer months, June shows weak (non-significant) increasing trends across all catchments (significant for one catchment in the south). Both July and August flows are dominated by decreasing, mostly non-significant, trends. Largest decreasing trends are found for August in the southwest and west, with four catchments in the southwest and southeast showing significant decreases. For autumn months, trends are dominated by increases. September shows the greatest diversity of trends with large, though non-significant, increasing trends in the northwest, and weak decreasing trends in the east and southeast. Both October and November are dominated by increasing trends, particularly the latter, whereby catchments in the southwest show significant increases over the fixed period 1900–2016. Figure 5Open in figure viewerPowerPoint As per Figure 1 but for monthly mean flows. Figure 6 evaluates the persistence of trends in monthly mean flows for varying start years. While all months show sensitivity of results to the period used to assess trends, the months where trends are most sensitive to start year are March, April, July, August, September and October. In March, long-term records tend to return increasing trends (significant for tests commencing in the 1920s and 1930s). By contrast, tests commencing in the 1970s return significant decreasing trends. Similar results are obtained for April, with tests commencing in the mid-1980s returning significant decreasing trends for many catchments, while tests commencing in the first half of the twentieth century return large (often significant) increasing trends. July and August show similar results, with tests commencing in the early record dominated by decreasing trends, whereas tests commencing in the late 1960s typically return large (often significant) increasing trends. In September, tests commencing between 1920 and 1960 show widespread decreasing trends across catchments, while tests commencing after 1960 show weak increasing and decreasing trends across catchments. Finally for October, tests commencing after 1970 tend to show large, often significant, decreasing trends, while tests commencing prior to the 1970 largely show increasing trends across catchments. These results highlight the importance of record length and again emphasise that the period of available observations is often unrepresentative of long-term trends in monthly flows. Figure 6Open in figure viewerPowerPoint As per Figure 2 but for monthly mean flows. Discussion This research investigated annual, seasonal and monthly trends in reconstructed flows for 51 Irish catchments over the period 1900–2016. We find increasing trends in annual flows in the northwest, west and southwest. Our seasonal assessment found increases in autumn and winter flows consistent with those found for precipitation by McElwain and Sweeney (2003) and Murphy et al. (2018). Seasonal trends are also consistent with Murphy et al. (2013) for respective periods of records. Our monthly assessment confirmed seasonal findings, with prominent increasing trends evident in western catchments during the winter half year (October–March). Our study shows the large variability in mean flows across Ireland. We find a change in the direction of trends in the mid-1970s, particularly in annual and spring mean flows. Ryan et al. (2021) found significant breakpoints between 1976 and 1979 for annual precipitation totals in their assessment of long-term trends in Irish precipitation. Similarly, Murphy et al. (2018) identified a step change in 1976 in their 1711–2016 rainfall series for Ireland. Both studies attribute this change to a switch to a predominantly positive phase of the North Atlantic Oscillation in the mid-1970s, previously noted in Ireland by Kiely (1999) and at a European scale by Lorenzo-Lacruz et al. (2022). Furthermore, McCarthy et al. (2015) highlight the influence of the Atlantic Multidecadal Oscillation (AMO) on summer precipitation in Ireland. Future research should prioritise investigating AMO influence on summer flows using these long-term reconstructions, with potential insights being useful for decadal forecasting and water management. Our findings highlight the sensitivity of trends to the period of record examined. For annual, spring and summer mean flows, trends in reconstructions for the period concurrent with observations were often unrepresentative of long-term trends. This highlights the importance of flow reconstructions for contextualising findings from shorter observed records. Reconstructions are subject to uncertainty, principally from the hydrological models employed and the underlying precipitation data (O'Connor et al., 2021). Close inspection of reconstructed and observed flows by O'Connor et al. (2021) and agreement between our results and those found in other studies suggest that our results are reliable. Finally, assessment of climate change impacts on seasonal mean flows for Irish catchments using the CMIP6 ensemble by Meresa et al. (2021, 2022) suggests that anthropogenic climate change is likely to be associated with increases in winter mean flows. This is consistent with trends in winter identified here for the west and northwest. While the direction of change in summer is uncertain, the majority of future simulations suggest substantial decreases. Our results show little evidence of persistent trends in summer flows, while trends commencing in recent decades show a tendency towards increasing summer flows. Future work should further investigate the disparity between observed and simulated changes in summer flows. Similar issues have been raised elsewhere (e.g. Hannaford, 2015). Conclusions This study investigated trends in reconstructed river flows (1900–2016) for 51 catchments across the island of Ireland at annual, seasonal and monthly timescales. For the full period of record increasing trends are evident for annual, winter and autumn mean flows, particularly for catchments in the west and northwest. No significant trends are found for spring and summer mean flows. 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