Chinese Journal of Applied Ecology ›› 2023, Vol. 34 ›› Issue (2): 566-576.doi: 10.13287/j.1001-9332.202302.016
• Reviews • Previous Articles
WANG Shengjie1,2, WANG Liwei1,2,3, ZHANG Mingjun1,2*
Received:
2022-02-13
Accepted:
2022-11-28
Online:
2023-02-15
Published:
2023-08-15
WANG Shengjie, WANG Liwei, ZHANG Mingjun. Methodology and application of precipitation isoscapes of stable hydrogen and oxygen isotopes[J]. Chinese Journal of Applied Ecology, 2023, 34(2): 566-576.
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URL: https://www.cjae.net/EN/10.13287/j.1001-9332.202302.016
[1] Bowen GJ, Cai Z, Fiorella RP, et al. Isotopes in the water cycle: Regional- to global-scale patterns and applications. Annual Review of Earth and Planetary Sciences, 2019, 47: 453-479 [2] Falster G, Konecky B, Madhavan M, et al. Imprint of the Pacific Walker circulation in global precipitation δ18O. Journal of Climate, 2021, 34: 8579-8597 [3] West JB, Bowen GJ, Dawson TE, et al. Isoscapes: Understanding Movement, Pattern, and Process on Earth through Isotope Mapping. Dordrecht: Springer, 2010: 1-511 [4] Bowen GJ. Isoscapes: Spatial pattern in isotopic biogeochemistry. Annual Review of Earth and Planetary Sciences, 2010, 38: 161-187 [5] Bowen GJ, Good SP. Incorporating water isoscapes in hydrological and water resource investigations. Wiley Interdisciplinary Reviews: Water, 2015, 2: 107-119 [6] Hollins SE, Hughes CE, Crawford J, et al. Rainfall isotope variations over the Australian continent: Implications for hydrology and isoscape applications. Science of the Total Environment, 2018, 645: 630-645 [7] Chesson LA, Barnette JE, Bowen GJ, et al. Applying the principles of isotope analysis in plant and animal ecology to forensic science in the Americas. Oecologia, 2018, 187: 1077-1094 [8] Good SP, Kennedy CD, Stalker JC, et al. Patterns of local and nonlocal water resource use across the western US determined via stable isotope intercomparisons. Water Resources Research, 2014, 50: 8034-8049 [9] Hobson KA, Wassenaar LI. Tracking Animal Migration with Stable Isotopes. 2nd Ed. London: Academic Press, 2019: 1-268 [10] Midhun M, Stevenson S, Cole JE. Oxygen isotopic signatures of major climate modes and implications for detectability in speleothems. Geophysical Research Letters, 2021, 48: e2020GL089515 [11] Tharammal T, Bala G, Paul A, et al. Orbitally driven evolution of Asian monsoon and stable water isotope ratios during the Holocene: Isotope-enabled climate model simulations and proxy data comparisons. Quaternary Science Reviews, 2021, 252: 106743 [12] Yao T, Masson-Delmotte V, Gao J, et al. A review of climatic controls on δ18O in precipitation over the Tibe-tan Plateau: Observations and simulations. Reviews of Geophysics, 2013, 51: 525-548 [13] Michelsen N, van Geldern R, Roβmann Y, et al. Comparison of precipitation collectors used in isotope hydro-logy. Chemical Geology, 2018, 488: 171-179 [14] Ankor MJ, Tyler JJ, Hughes CE. Development of an autonomous, monthly and daily, rainfall sampler for isotope research. Journal of Hydrology, 2019, 575: 31-41 [15] Koehler G. Snow gauge undercatch and its effect on the hydrogen and oxygen stable isotopic composition of precipitation. Isotopes in Environmental and Health Studies, 2019, 55: 404-418 [16] Hughes CE, Crawford J. Spatial and temporal variation in precipitation isotopes in the Sydney Basin, Australia. Journal of Hydrology, 2013, 489: 42-55 [17] Terzer-Wassmuth S, Ortega L, Araguás-Araguás L, et al. The first IAEA inter-laboratory comparison exercise in Latin America and the Caribbean for stable isotope analyses of water samples. Isotopes in Environmental and Health Studies, 2020, 56: 391-401 [18] Hatvani IG, Szatmári G, Kern Z, et al. Geostatistical evaluation of the design of the precipitation stable isotope monitoring network for Slovenia and Hungary. Environment International, 2021, 146: 106263 [19] Wang S, Lei S, Zhang M, et al. Spatial and seasonal isotope variability in precipitation across China: Monthly isoscapes based on regionalized fuzzy clustering. Journal of Climate, 2022, 35: 3411-3425 [20] Vystavna Y, Matiatos I, Wassenaar LI. Temperature and precipitation effects on the isotopic composition of global precipitation reveal long-term climate dynamics. Scientific Reports, 2021, 11: 18503 [21] Terzer S, Wassenaar LI, Araguás-Araguás LJ, et al. Global isoscapes for δ18O and δ2H in precipitation: Improved prediction using regionalized climatic regression models. Hydrology and Earth System Sciences, 2013, 17: 4713-4728 [22] Zhang M, Wang S. A review of precipitation isotope studies in China: Basic pattern and hydrological process. Journal of Geographical Sciences, 2016, 26: 921-938 [23] Putman AL, Bowen GJ. A global database of the stable isotopic ratios of meteoric and terrestrial waters. Hydro-logy and Earth System Sciences, 2019, 23: 4389-4396 [24] 郑淑蕙, 侯发高, 倪葆龄. 我国大气降水的氢氧稳定同位素研究. 科学通报, 1983, 28(13): 801-806 [25] 张洪平. 我国大气降水稳定同位素背景值的研究. 勘察科学技术, 1989(6): 6-12 [26] 赵珂经, 顾慰祖, 顾文燕, 等. 中国降水同位素站网. 水文, 1995, 15(5): 25-27 [27] 宋献方, 柳鉴容, 孙晓敏, 等. 基于CERN的中国大气降水同位素观测网络. 地球科学进展, 2007, 22(7): 738-747 [28] Liu J, Song X, Yuan G, et al. Stable isotopic compositions of precipitation in China. Tellus B, 2014, 66: 22567 [29] Yu W, Yao T, Thompson LG, et al. Temperature signals of ice core and speleothem isotopic records from Asian monsoon region as indicated by precipitation δ18O. Earth and Planetary Science Letters, 2021, 554: 116665 [30] Zhou H, Zhang X, Yao T, et al. Variation of δ18O in precipitation and its response to upstream atmospheric convection and rainout: A case study of Changsha station, south-central China. Science of the Total Environment, 2019, 659: 1199-1208 [31] Li Y, An W, Pang H, et al. Variations of stable isotopic composition in atmospheric water vapor and their controlling factors: A 6-year continuous sampling study in Nanjing, Eastern China. Journal of Geophysical Research: Atmospheres, 2020, 125: e2019JD031697 [32] Chen F, Zhang M, Wang S, et al. Environmental controls on stable isotopes of precipitation in Lanzhou, China: An enhanced network at city scale. Science of the Total Environment, 2017, 609: 1013-1022 [33] Wu H, Zhang C, Li X, et al. Hydrometeorological processes and moisture sources in the northeastern Tibe-tan Plateau: Insights from a 7-yr study on precipitation isotopes. Journal of Climate, 2022, 35: 2919-2931 [34] Zhou J, Li T. A tentative study of the relationship between annual δ18O & δD variations of precipitation and atmospheric circulations: A case from Southwest China. Quaternary International, 2018, 479: 117-127 [35] Yurtsever Y, Gat JR. Atmospheric waters// Gat JR, Gonfiantini R, eds. Stable Isotope Hydrology: Deute-rium and Oxygen-18 in the Water Cycle. Vienna: International Atomic Energy Agency, 1981: 103-142 [36] Birks SJ, Gibson JJ, Gourcy L, et al. Maps and animations offer new opportunities for studying the global water cycle. Eos, 2002, 83: 406 [37] Masiol M, Zannoni D, Stenni B, et al. Spatial distribution and interannual trends of δ18O, δ2H, and deute-rium excess in precipitation across North-Eastern Italy. Journal of Hydrology, 2021, 598: 125749 [38] Valdivielso S, Hassanzadeh A, Vázquez-Suñé E, et al. Spatial distribution of meteorological factors controlling stable isotopes in precipitation in Northern Chile. Journal of Hydrology, 2022, 605: 127380 [39] Kern Z, Kohán B, Leuenberger M. Precipitation isoscape of high reliefs: Interpolation scheme designed and tested for monthly resolved precipitation oxygen isotope records of an Alpine domain. Atmospheric Chemistry and Physics, 2014, 14: 1897-1907 [40] Farquhar GD, Lloyd J, Taylor JA, et al. Vegetation effects on the isotope composition of oxygen in atmospheric CO2. Nature, 1993, 363: 439-443 [41] Bowen GJ, Wilkinson B. Spatial distribution of δ18O in meteoric precipitation. Geology, 2002, 30: 315-318 [42] Bowen GJ, Revenaugh J. Interpolating the isotopic composition of modern meteoric precipitation. Water Resources Research, 2003, 39: 1299 [43] Bowen GJ, Wassenaar LI, Hobson KA. Global application of stable hydrogen and oxygen isotopes to wildlife forensics. Oecologia, 2005, 143: 337-348 [44] Terzer-Wassmuth S, Wassenaar LI, Welker JM, et al. Improved high-resolution global and regionalized isoscapes of δ18O, δ2H and d-excess in precipitation. Hydrological Processes, 2021, 35: e14254 [45] Araguás-Araguás L, Froehlich K, Rozanski K. Deute-rium and oxygen-18 isotope composition of precipitation and atmospheric moisture. Hydrological Processes, 2000, 14: 1341-1355 [46] Kong Y, Wang K, Li J, et al. Stable isotopes of precipitation in China: A consideration of moisture sources. Water, 2019, 11: 1239 [47] Liu Z, Tian L, Chai X, et al. A model-based determination of spatial variation of precipitation δ18O over China. Chemical Geology, 2008, 249: 203-212 [48] 李亚举, 张明军, 王圣杰, 等. 基于温度作为辅助变量的中国降水δ18O空间分布特征. 地理科学进展, 2011, 30(11): 1387-1394 [49] Zhao P, Guo Z, She D, et al. Spatial distribution of the oxygen-18 in precipitation in China based on a new empirical model. Journal of Mountain Science, 2019, 16: 2605-2614 [50] Sturm C, Zhang Q, Noone D. An introduction to stable water isotopes in climate models: Benefits of forward proxy modelling for paleoclimatology. Climate of the Past, 2010, 6: 115-129 [51] Botsyun S, Sepulchre P, Donnadieu Y, et al. Revised paleoaltimetry data show low Tibetan Plateau elevation during the Eocene. Science, 2019, 363: eaaq1436 [52] Zhang H, Zhang X, Cai Y, et al. A data-model compa-rison pinpoints Holocene spatiotemporal pattern of East Asian summer monsoon. Quaternary Science Reviews, 2021, 261: 106911 [53] Galewsky J, Steen-Larsen HC, Field RD, et al. Stable isotopes in atmospheric water vapor and applications to the hydrologic cycle. Reviews of Geophysics, 2016, 54: 809-865 [54] Bailey A, Noone D, Cobb K, et al. Water Isotopes and Climate. Boulder: United States Climate Variability and Predictability, 2021: 1-41 [55] Joussaume S, Sadourny R, Jouzel J. A general circulation model of water isotope cycles in the atmosphere. Nature, 1984, 311: 24-29 [56] Cauquoin A, Werner M. High-resolution nudged isotope modeling with ECHAM6-wiso: Impacts of updated model physics and ERA5 reanalysis data. Journal of Advances in Modeling Earth Systems, 2021, 13: e2021MS002532 [57] Fiorella RP, Siler N, Nusbaumer J, et al. Enhancing understanding of the hydrological cycle via pairing of process-oriented and isotope ratio tracers. Journal of Advances in Modeling Earth Systems, 2021, 13: e2021MS002648 [58] Conroy JL, Cobb KM, Noone D. Comparison of precipitation isotope variability across the tropical Pacific in observations and SWING2 model simulations. Journal of Geophysical Research: Atmospheres, 2013, 118: 5867-5892 [59] 王学界, 章新平, 张婉君, 等. iGCM模拟全球典型站点降水中δ18O的效果评价以及香港站δ18O年际震荡的原因探讨. 第四纪研究, 2018, 38(6): 1518-1531 [60] Peng P, Zhang XJ, Chen J. Bias correcting isotope-equipped GCMs outputs to build precipitation oxygen isoscape for eastern China. Journal of Hydrology, 2020, 589: 125153 [61] Yang S, Zhang M, Wang S, et al. Interannual trends in stable oxygen isotope composition in precipitation of China during 1979-2007: Spatial incoherence. Quaternary International, 2017, 454: 25-37 [62] Che Y, Zhang M, Wang S, et al. Stable water isotopes of precipitation in China simulated by SWING2 models. Arabian Journal of Geosciences, 2016, 9: 732 [63] Gao J, He Y, Masson-Delmotte V, et al. ENSO effects on annual variations of summer precipitation stable isotopes in Lhasa, southern Tibetan Plateau. Journal of Climate, 2018, 31: 1173-1182 [64] Cai Z, Tian L, Bowen GJ. Spatial-seasonal patterns reveal large-scale atmospheric controls on Asian Monsoon precipitation water isotope ratios. Earth and Planetary Science Letters, 2018, 503: 158-169 [65] Shi X, Risi C, Pu T, et al. Variability of isotope composition of precipitation in the southeastern Tibetan Pla-teau from the synoptic to seasonal time scale. Journal of Geophysical Research: Atmospheres, 2020, 125: e2019JD031751 [66] Shi Y, Wang S, Wang L, et al. Isotopic evidence in modern precipitation for the westerly meridional movement in Central Asia. Atmospheric Research, 2021, 259: 105698 [67] Man W, Zhou T, Jiang J, et al. Moisture sources and climatic controls of precipitation stable isotopes over the Tibetan Plateau in water-tagging simulations. Journal of Geophysical Research: Atmospheres, 2022, 127: e2021JD036321 [68] Nelson DB, Basler D, Kahmen A. Precipitation isotope time series predictions from machine learning applied in Europe. Proceedings of the National Academy of Sciences of the United States of America, 2021, 118: e2024-107118 [69] Xu T, Liang F. Machine learning for hydrologic sciences: An introductory overview. Wiley Interdisciplinary Reviews: Water, 2021, 8: e1533 [70] Lisowska-Gaczorek A, Cienkosz-Stepańczak B, Szostek K. Oxygen stable isotopes variation in water precipitation in Poland: Anthropological applications. Anthropological Review, 2017, 80: 57-70 [71] Liu J, An Z. Global-scale altitude effect on leaf wax n-alkane δD values in terrestrial higher plants. Science China: Earth Sciences, 2021, 64: 825-834 [72] Nan Y, Tian L, He Z, et al. The value of water isotope data on improving process understanding in a glacierized catchment on the Tibetan Plateau. Hydrology and Earth System Sciences, 2021, 25: 3653-3673 [73] Liu J, Song X, Yuan G, et al. Stable isotopes of summer monsoonal precipitation in southern China and the moisture sources evidence from δ18O signature. Journal of Geographical Sciences, 2008, 18: 155-165 [74] Liu Z, Bowen GJ, Welker JM. Atmospheric circulation is reflected in precipitation isotope gradients over the conterminous United States. Journal of Geophysical Research: Atmospheres, 2010, 115: D22120 [75] Vachon RW, Welker JM, White JWC, et al. Monthly precipitation isoscapes (δ18O) of the United States: Connections with surface temperatures, moisture source conditions, and air mass trajectories. Journal of Geophysical Research: Atmospheres, 2010, 115: D21126 [76] Tindall JC, Valdes PJ, Sime LC. Stable water isotopes in HadCM3: Isotopic signature of El Niño-Southern Oscillation and the tropical amount effect. Journal of Geophysical Research: Atmospheres, 2009, 114: D04111 [77] Liu Z, Yoshmura K, Bowen GJ, et al. Pacific-North American teleconnection controls on precipitation isotopes (δ18O) across the contiguous United States and adjacent regions: A GCM-based analysis. Journal of Climate, 2014, 27: 1046-1061 [78] Sun C, Tian L, Shanahan TM, et al. Isotopic variability in tropical cyclone precipitation is controlled by Rayleigh distillation and cloud microphysics. Communications Earth and Environment, 2022, 3: 50 [79] Liu Z, Yoshimura K, Bowen GJ, et al. Paired oxygen isotope records reveal modern North American atmosphe-ric dynamics during the Holocene. Nature Communications, 2014, 5: 3701 [80] Chiang JCH, Herman MJ, Yoshimura K, et al. Enriched East Asian oxygen isotope of precipitation indicates reduced summer seasonality in regional climate and westerlies. Proceedings of the National Academy of Sciences of the United States of America, 2020, 117: 14745-14750 [81] Fekete BM, Gibson JJ, Aggarwal P, et al. Application of isotope tracers in continental scale hydrological mode-ling. Journal of Hydrology, 2006, 330: 444-456 [82] Bowen GJ, Kennedy CD, Liu Z, et al. Water balance model for mean annual hydrogen and oxygen isotope distributions in surface waters of the contiguous United States. Journal of Geophysical Research: Biogeosciences, 2011, 116: G04011 [83] Ogrinc N, Kocman D, Miljevic' N, et al. Distribution of H and O stable isotopes in the surface waters of the Sava River, the major tributary of the Danube River. Journal of Hydrology, 2018, 565: 365-373 [84] Nan Y, He Z, Tian F, et al. Can we use precipitation isotope outputs of isotopic general circulation models to improve hydrological modeling in large mountainous catchments on the Tibetan Plateau? Hydrology and Earth System Sciences, 2021, 25: 6151-6172 [85] Gibson JJ, Holmes T, Stadnyk TA, et al. Isotopic constraints on water balance and evapotranspiration partitioning in gauged watersheds across Canada. Journal of Hydrology: Regional Studies, 2021, 37: 100878 [86] Yang J, Dudley BD, Montgomery K, et al. Characterizing spatial and temporal variation in 18O and 2H content of New Zealand river water for better understanding of hydrologic processes. Hydrological Processes, 2020, 34: 5474-5488 [87] Gibson JJ, Holmes T, Stadnyk TA, et al. 18O and 2H in streamflow across Canada. Journal of Hydrology: Regional Studies, 2020, 32: 100754 [88] Matiatos I, Wassenaar LI. Stable isotope patterns reveal widespread rainy-period-biased recharge in phreatic aquifers across Greece. Journal of Hydrology, 2019, 568: 1081-1092 [89] Bedaso Z, Wu SY. Linking precipitation and ground-water isotopes in Ethiopia: Implications from local meteoric water lines and isoscapes. Journal of Hydrology, 2021, 596: 126074 [90] Bowen GJ, Guo JS, Allen ST. A 3-D groundwater isoscape of the contiguous USA for forensic and water resource science. PLoS One, 2022, 17(1): e0261651 [91] West JB, Sobek A, Ehleringer JR. A simplified GIS approach to modeling global leaf water isoscapes. PLoS One, 2008, 3(6): e2447 [92] 潘素敏, 张明军, 王圣杰, 等. 基于GCM的中国土壤水中δ18O的分布特征. 生态学杂志, 2017, 36(6): 1727-1738 [93] Hobson KA, Van Wilgenburg SL, Wassenaar LI, et al. Linking hydrogen (δ2H) isotopes in feathers and precipitation: Sources of variance and consequences for assignment to isoscapes. PLoS One, 2012, 7(4): e35137 [94] Vander Zanden HB, Nelson DM, Wunder MB, et al. Application of isoscapes to determine geographic origin of terrestrial wildlife for conservation and management. Biological Conservation, 2018, 228: 268-280 [95] Han Z, Wang HT, Kardynal KJ, et al. Stable isotopes (δ2H) in feathers identify non-breeding origins of the endangered Jankowski’s Bunting. Journal of Ornitho-logy, 2021, 162: 987-995 [96] Vander Zanden HB, Wunder MB, Hobson KA, et al. Contrasting assignment of migratory organisms to geographic origins using long-term versus year-specific precipitation isotope maps. Methods in Ecology and Evolution, 2014, 5: 891-900 [97] Reich MS, Flockhart DTT, Norris DR, et al. Conti-nuous-surface geographic assignment of migratory animals using strontium isotopes: A case study with monarch butterflies. Methods in Ecology and Evolution, 2021, 12: 2445-2457 [98] Crowley BE, Bataille CP, Haak BA, et al. Identifying nesting grounds for juvenile migratory birds with dual isotope: An initial test using North American raptors. Ecosphere, 2021, 12: e03765 [99] Carter JF, Yates HSA, Tinggi U. A global survey of the stable isotope and chemical compositions of bottled and canned beers as a guide to authenticity. Science and Justice, 2015, 55: 18-26 [100] Guo R, Wang S, Zhang M, et al. Stable hydrogen and oxygen isotope characteristics of bottled water in China: A consideration of water source. Water, 2019, 11: 1065 [101] Behkami S, Gholami R, Gholami M, et al. Precipita-tion isotopic information: A tool for building the data base to verify milk geographical origin traceability. Food Control, 2020, 107: 106780 [102] Watkinson CJ, Gasson P, Rees GO, et al. The deve-lopment and use of isoscapes to determine the geogra-phical origin of Quercus spp. in the United States. Forests, 2020, 11: 862 [103] Meier-Augenstein W. Forensic stable isotope signatures: Comparing, geo-locating, detecting linkage. Wiley Interdisciplinary Reviews: Forensic Science, 2019, 1: e1339 [104] Reynard LM, Ryan SE, Guirguis M, et al. Mediterranean precipitation isoscape preserved in bone collagen δ2H. Scientific Reports, 2020, 10: 8579 [105] West AG, February EC, Bowen GJ. Spatial analysis of hydrogen and oxygen stable isotopes (‘isoscapes’) in ground water and tap water across South Africa. Journal of Geochemical Exploration, 2014, 145: 213-222 [106] Wang S, Zhang M, Bowen GJ, et al. Water source signatures in the spatial and seasonal isotope variation of Chinese tap waters. Water Resources Research, 2018, 54: 9131-9143 [107] Du M, Zhang M, Wang S, et al. Stable isotope reveals tap water source under different water supply modes in the eastern margin of the Qinghai-Tibet Plateau. Water, 2019, 11: 2578 [108] 韦飞黎, 李双成, 余武生, 等. 降水稳定同位素研究的历史与现状——基于文献计量学及网络分析方法. 生态学报, 2019, 39(7): 2634-2643 [109] 李佳奇, 黄亚楠, 石培君, 等. 陕北黄土区大气降水同位素特征及其水汽来源. 应用生态学报, 2022, 33(6): 1459-1465 [110] 檀康达, 王仕琴, 郑文波. 基于卫星降水产品的华北北纬38°带降水氢氧同位素时空特征及水汽来源. 应用生态学报, 2021, 32(6): 1951-1962 [111] 隋明浈, 张瑛, 徐庆, 等. 水汽来源和环境因子对湖南会同大气降水氢氧同位素组成的影响. 应用生态学报, 2020, 31(6): 1791-1799 [112] Pauli JN, Newsome SD, Cook JA, et al. Why we need a centralized repository for isotopic data. Proceedings of the National Academy of Sciences of the United States of America, 2017, 114: 2997-3001 [113] Konecky BL, McKay NP, Churakova OV, et al. The Iso2k database: A global compilation of paleo-δ18O and δ2H records to aid understanding of Common Era climate. Earth System Science Data, 2020, 12: 2261-2288 [114] Pauli JN, Steffan SA, Newsome SD. It is time for IsoBank. BioScience, 2015, 65: 229-230 |
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