L.J. Lambán
About
L.J. Lambán is a scholar working on Water Science and Technology, Geochemistry and Petrology and Earth-Surface Processes.
According to data from OpenAlex, L.J. Lambán has authored 33 papers receiving a total of 514 indexed citations (citations by other indexed papers that have themselves been cited), including 15 papers in Water Science and Technology, 13 papers in Geochemistry and Petrology and 13 papers in Earth-Surface Processes. Recurrent topics in L.J. Lambán's work include Hydrology and Watershed Management Studies (15 papers), Karst Systems and Hydrogeology (13 papers) and Groundwater and Isotope Geochemistry (13 papers). L.J. Lambán is often cited by papers focused on Hydrology and Watershed Management Studies (15 papers), Karst Systems and Hydrogeology (13 papers) and Groundwater and Isotope Geochemistry (13 papers). L.J. Lambán collaborates with scholars based in Spain, Chile and Uruguay. L.J. Lambán's co-authors include Jorge Jódar, Emílio Custódio, Sergio Martos‐Rosillo, Christian Herrera, Javier Urrutia, Antonio González Ramón, Albert Soler, Ana Ruiz‐Constán, Ruth Soto and Carolina Gamboa and has published in prestigious journals such as The Science of The Total Environment, Journal of Hydrology and Environmental Modelling & Software.
In The Last Decade
L.J. Lambán
33 papers receiving 495 citations
Peers — A (Enhanced Table)
Peers by citation overlap · career bar shows stage (early→late) cites · hero ref
| Name | h | Career | Trend | Papers | Cites | |||||
|---|---|---|---|---|---|---|---|---|---|---|
| L.J. Lambán Spain | 15 | 242 | 210 | 203 | 129 | 119 | 33 | 514 | ||
| Sam Earman United States | 9 | 270 1.1× | 280 1.3× | 211 1.0× | 180 1.4× | 38 0.3× | 14 | 553 | ||
| Javier Urrutia Chile | 14 | 180 0.7× | 103 0.5× | 135 0.7× | 130 1.0× | 58 0.5× | 28 | 471 | ||
| Marty D. Frisbee United States | 13 | 196 0.8× | 352 1.7× | 255 1.3× | 156 1.2× | 34 0.3× | 29 | 562 | ||
| Shive Prakash India | 16 | 358 1.5× | 292 1.4× | 345 1.7× | 118 0.9× | 25 0.2× | 28 | 670 | ||
| Vincent Marc France | 11 | 184 0.8× | 339 1.6× | 258 1.3× | 74 0.6× | 40 0.3× | 23 | 633 | ||
| Davood Mahmoodzadeh Iran | 8 | 293 1.2× | 95 0.5× | 267 1.3× | 68 0.5× | 88 0.7× | 17 | 535 | ||
| Werner Balderer Switzerland | 14 | 349 1.4× | 155 0.7× | 289 1.4× | 105 0.8× | 56 0.5× | 29 | 654 | ||
| Suzanne Hollins Australia | 13 | 314 1.3× | 102 0.5× | 153 0.8× | 120 0.9× | 54 0.5× | 17 | 529 | ||
| Nour‐Eddine Laftouhi Morocco | 12 | 165 0.7× | 201 1.0× | 196 1.0× | 58 0.4× | 27 0.2× | 39 | 496 | ||
| Sylvie Ogier France | 10 | 132 0.5× | 83 0.4× | 124 0.6× | 109 0.8× | 146 1.2× | 12 | 477 |
Countries citing papers authored by L.J. Lambán
Since
Specialization
Citations
This map shows the geographic impact of L.J. Lambán's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by L.J. Lambán with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites L.J. Lambán more than expected).
Fields of papers citing papers by L.J. Lambán
Since
Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences
This network shows the impact of papers produced by L.J. Lambán. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by L.J. Lambán. The network helps show where L.J. Lambán may publish in the future.
Co-authorship network of co-authors of L.J. Lambán
This figure shows the co-authorship network connecting the top 25 collaborators of L.J. Lambán. A scholar is included among the top collaborators of L.J. Lambán based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with L.J. Lambán. L.J. Lambán is excluded from the visualization to improve readability, since they are connected to all nodes in the network.
All Works
1.
Jódar, Jorge, et al.. (2024). Ancestral managed aquifer recharge systems and their impacts on the flow regime of a semi-arid alpine basin (Sierra Nevada, Spain). Journal of Hydrology Regional Studies. 54. 101870–101870.
2.
Jódar, Jorge, Javier Urrutia, Christian Herrera, et al.. (2023). The catastrophic effects of groundwater intensive exploitation and Megadrought on aquifers in Central Chile: Global change impact projections in water resources based on groundwater balance modeling. The Science of The Total Environment. 914. 169651–169651.
3.
Jódar, Jorge, Sergio Martos‐Rosillo, Emílio Custódio, et al.. (2022). The Recharge Channels of the Sierra Nevada Range (Spain) and the Peruvian Andes as Ancient Nature-Based Solutions for the Ecological Transition. Water. 14(19). 3130–3130.
4.
Jódar, Jorge, Antonio González Ramón, Ana Ruiz‐Constán, et al.. (2022). Artificial recharge by means of careo channels versus natural aquifer recharge in a semi-arid, high-mountain watershed (Sierra Nevada, Spain). The Science of The Total Environment. 825. 153937–153937.
5.
Jódar, Jorge, et al.. (2021). Identification of Natural and Anthropogenic Geochemical Processes Determining the Groundwater Quality in Port del Comte High Mountain Karst Aquifer (SE, Pyrenees). Water. 13(20). 2891–2891.
6.
Jódar, Jorge, L.J. Lambán, Sergio Martos‐Rosillo, et al.. (2021). Isotopic content in high mountain karst aquifers as a proxy for climate change impact in Mediterranean zones: The Port del Comte karst aquifer (SE Pyrenees, Catalonia, Spain). The Science of The Total Environment. 790. 148036–148036.
7.
Jódar, Jorge, Antonio González Ramón, Ana Ruiz‐Constán, et al.. (2021). Artificial Recharge by Means of Careo Channels Versus Natural Aquifer Recharge in a Semi-Arid, High-Mountain Watershed (Sierra Nevada, Spain). SSRN Electronic Journal.
8.
Jódar, Jorge, Albert Soler, L.J. Lambán, et al.. (2020). Evaluation of natural background levels of high mountain karst aquifers in complex hydrogeological settings. A Gaussian mixture model approach in the Port del Comte (SE, Pyrenees) case study. The Science of The Total Environment. 756. 143864–143864.
9.
Ramón, Antonio González, Jorge Jódar, Sergio Martos‐Rosillo, et al.. (2020). Hydrometeorological factors determining the development of water table cave patterns in high alpine zones. The Ordesa and Monte Perdido National Park, NE Spain. International Journal of Speleology. 49(3). 249–270.
10.
Jódar, Jorge, Antonio González Ramón, Sergio Martos‐Rosillo, et al.. (2020). Snowmelt as a determinant factor in the hydrogeological behaviour of high mountain karst aquifers: The Garcés karst system, Central Pyrenees (Spain). The Science of The Total Environment. 748. 141363–141363.
11.
Jódar, Jorge, Félix Rubio, Emílio Custódio, et al.. (2020). Hydrogeochemical, isotopic and geophysical characterization of saline lake systems in semiarid regions: The Salada de Chiprana Lake, Northeastern Spain. The Science of The Total Environment. 728. 138848–138848.
12.
Jódar, Jorge, Albert Soler, Iñaki Vadillo, et al.. (2018). Contribution of isotopic research techniques to characterize high-mountain-Mediterranean karst aquifers: The Port del Comte (Eastern Pyrenees) aquifer. The Science of The Total Environment. 656. 209–230.
13.
Jódar, Jorge, Sergio Martos‐Rosillo, Ana Ruiz‐Constán, et al.. (2017). Combination of lumped hydrological and remote-sensing models to evaluate water resources in a semi-arid high altitude ungauged watershed of Sierra Nevada (Southern Spain). The Science of The Total Environment. 625. 285–300.
14.
Jódar, Jorge, Sergio Martos‐Rosillo, Ana Ruiz‐Constán, et al.. (2017). Groundwater discharge in high-mountain watersheds: A valuable resource for downstream semi-arid zones. The case of the Bérchules River in Sierra Nevada (Southern Spain). The Science of The Total Environment. 593-594. 760–772.
15.
Jódar, Jorge, Emílio Custódio, L.J. Lambán, et al.. (2016). Vertical variation in the amplitude of the seasonal isotopic content of rainfall as a tool to jointly estimate the groundwater recharge zone and transit times in the Ordesa and Monte Perdido National Park aquifer system, north-eastern Spain. The Science of The Total Environment. 573. 505–517.
16.
Jódar, Jorge, Emílio Custódio, Marcello Liotta, et al.. (2016). Correlation of the seasonal isotopic amplitude of precipitation with annual evaporation and altitude in alpine regions. The Science of The Total Environment. 550. 27–37.
17.
Custódio, Emílio, Guillermo Chong, L.J. Lambán, et al.. (2015). Groundwater flow in a closed basin with a saline shallow lake in a volcanic area: Laguna Tuyajto, northern Chilean Altiplano of the Andes. The Science of The Total Environment. 541. 303–318.
18.
Jódar, Jorge, L.J. Lambán, A. Medina, & Emílio Custódio. (2014). Exact analytical solution of the convolution integral for classical hydrogeological lumped-parameter models and typical input tracer functions in natural gradient systems. Journal of Hydrology. 519. 3275–3289.
19.
Lambán, L.J., et al.. (2009). Primeros resultados obtenidos sobre el funcionamiento hidrogeológico de la Laguna de Estaña y su relación con el acuífero de Estopiñán (Huesca, España). BOLETÍN GEOLÓGICO Y MINERO. 120(3). 443–458.
20.
García-Aróstegui, J. L., et al.. (2006). Efectos de la explotación intensiva de aguas subterráneas en la ciudad de murcia (España) en épocas de sequía: orientaciones para una explotación sostenible. BOLETÍN GEOLÓGICO Y MINERO. 117(3). 389–400.
Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.
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