| Records |
Author  |
Ruffino, B.; Campo, G.; Crutchik, D.; Reyes, A.; Zanetti, M. |
| Title |
Drinking Water Supply in the Region of Antofagasta (Chile): A Challenge between Past, Present and Future |
Type |
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| Year |
2022 |
Publication |
International Journal of Environmental Research and Public Health |
Abbreviated Journal |
Int. J. Environ. Res. Public Health |
| Volume |
19 |
Issue |
21 |
Pages |
14406 |
| Keywords |
water scarcity; arsenic contamination; mining; Agua Potable Rural program; Chilean Water Code; climate change; water treatment plant; environmental sanitary engineering; SDG6; clean water and sanitation |
| Abstract |
Since the mid-nineteen century, when the first mining companies were established in the region of Antofagasta to extract saltpeter, mining managers and civil authorities have always had to face a number of problems to secure a water supply sufficient for the development of industrial activities and society. The unique features of the region, namely the scarcity of rainfall, the high concentration of arsenic in freshwaters and the increasing pressure of the mining sector, have made the supply of drinking water for local communities a challenge. In the 1950s, the town of Antofagasta experienced a serious drinking water crisis. The 300 km long aqueduct starting from the Toconce catchment, opened in 1958, temporarily ended this shortage of drinking water but created an even more dramatic problem. The concentration of arsenic in the water consumed by the population had grown by approx. ten times, reaching the value of 0.860 mg/L and seriously affecting people's health. The water treatment plants (WTPs) which were installed starting from the 1970s in the region (namely the Old and New Salar del Carmen in Antofagasta and Cerro Topater in Calama, plus the two recent desalination plants in Antofagasta and Tocopilla), have ensured, since 2014, that the drinking water coverage in the urban areas was practically universal (>99.9%). However, the rural areas have continued to experience significant shortcomings regarding their capacity to ensure the quality and continuity of the water supply service in the long run. Presently, approx. 42% of the rural population of the region of Antofagasta does not have a formal supply of drinking water. The recent amendments to the Chilean Water Code (March 2022) and the interventions carried out in the framework of the Agua Potable Rural (APR) program were intended to reduce the socio-ecological inequalities due to the lack of drinking water in the semi-concentrated and isolated rural population. |
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1660-4601 |
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WOS:000881328000001 |
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UAI @ alexi.delcanto @ |
Serial |
1659 |
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| Author |
Werlinger, F.; Segura, C.; Martinez, J.; Osorio-Roman, I.; Jara, D.; Yoon, S.J.; Gualdron-Reyes, A.F. |
| Title |
Current Progress of Efficient Active Layers for Organic, Chalcogenide and Perovskite-Based Solar Cells: A Perspective |
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| Year |
2023 |
Publication |
Energies |
Abbreviated Journal |
Energies |
| Volume |
16 |
Issue |
16 |
Pages |
5868 |
| Keywords |
light harvest; ingorganic molecules; metal chalcogenides; metal halide perovskites; active layer |
| Abstract |
Photovoltaics has become one of the emerging alternatives to progressively supply/replace conventional energy sources, considering the potential exploitation of solar energy. Depending on the nature of the light harvester to influence on its light-absorption capability and the facility to produce electricity, different generations of solar devices have been fabricated. Early studies of organic molecules (dye sensitizers) with good absorption coefficients, going through metal chalcogenides and, lastly, the timely emergence of halide perovskites, have promoted the development of novel and low-cost solar cells with promising photoconversion efficiency (PCE), close to the well-established Si-based devices. However, main drawbacks such as the degradation/photocorrosion of the active layer, the existence of intrinsic defect sites, and the inherent toxicity of the material due to the presence of some harmful elements have blocked the future commercialization of the above kind of solar cells. In this review, we highlight the current progress in achieving efficient photomaterials for organic, chalcogenides and halide perovskites-based solar cells with the purpose of achieving high PCE values, some of which are breakthroughs in this research topic, and the diverse approaches used to extend the stability of the active layer and improve the performance of the solar devices. |
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1996-1073 |
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WOS:001057161000001 |
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UAI @ alexi.delcanto @ |
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1884 |
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