ALBERT — All Library Books, journals and Electronic Records Telegrafenberg

1

Unknown

Multi-isotope characterization of water resources for domestic supply in Ljubljana, Slovenia (2020)

Vreča, Polona ; Nagode, Klara ; Kanduč, Tjaša ; [et al.]

PANGAEA

add to mindlist on the mindlist

Details

Publication Date: 2023-05-05

Description: The Ljubljansko polje and Ljubljansko barje aquifer system are the two most important groundwater sources for the Slovenia capital Ljubljana and its surroundings. The groundwater is pumped from 4 wellfields on Ljubljansko polje and one wellfield on Ljubljansko barje. In the central water distribution system some settlements are supplied with water from a single water plant, while some receive water from two or more facilities, depending on the volume of consumed water and pressure conditions. In Ljubljana, the water is prepared in a local water supply system without any technical water preparation procedures and is only chlorinated occasionally. Public Water Utility JP VODOVOD KANALIZACIJA SNAGA Ljubljana (JP VOKA SNAGA) monitors the microbiological and chemical parameters of drinking water at all stages. In 2018 started a new IAEA Coordinated Project F33024 "Use of Isotope Techniques for the Evaluation of Water Sources for Domestic Supply in Urban Areas" in which researchers from 16 countries worldwide participate. The Specific Slovenian Research Objectives in CRP are to improve the assessment of most important freshwater resources for domestic supply using environment isotopes, to select significant environmental isotopes for future monitoring that will enable better understanding and interpretation of water interactions important for water managers of JP VOKA SNAGA to predict the availability and quality of freshwater resources for Ljubljana domestic water supply and to develop together with JP VOKA SNAGA and CRP project partners guidelines on integrating environmental isotopes to assist water managers in the planning, designing, and management of freshwater resources for domestic supply in urban environments. Based on the synthesis of the results from previous investigations in the area and the experiences of JP VOKA SNAGA, 97 sampling sites in the Ljubljana water supply system were selected. Sampling sites were selected according to the water supply area and according to the type of sampling sites. Selection according to the type of sampling site in the water supply system includes 6 different types: wells (VD; 44 samples), joint exits from water pumping station (ZV; 7), reservoirs (VH; 23), water treatment locations (PV; 2), drinking water fountains (PIT; 13) and water tap in public buildings (PJ). Additionally, 10 sampling sites were selected including water taps in 2 public and 8 private buildings (PP) which are not included in regular monitoring of JP VOKA SNAGA. Selection according to the water supply area includes 8 different areas: 4 main water fields: Kleče (A), Hrastje (B), Brest (C), Jarški prod (D), Šentvid (E), and 4 areas where the water is mixed from two or three different supply areas: Hrastje/Jarški prod (F), Kleče/Brest (G), Kleče/Hrastje/Jarški prod (H) and Kleče/Hrastje/Brest (I2). Finally, sampling sites on River Sava (R: Brod, Črnuče, and Šentjakob) and at the outflow from wastewater treatment plant (CČN) were also selected. Sampling was performed between 06.09.2018 and 29.11.2018. This database is summarized results of in-situ measurements (water temperature and electrical conductivity) and laboratory analysis (pH, total alkalinity, the concentration of total arsenic in water, isotope composition of oxygen, hydrogen and carbon in dissolved inorganic carbon).

Keywords: Alkalinity, total; arsenic; Arsenic; Conductivity, electrical; DATE/TIME; domestic water supply system; isotope composition; isotopes; LATITUDE; Ljubljana_groundwater; Ljubljana, Slovenia; Location; Location type; LONGITUDE; Mass spectrometry; MULT; Multiple investigations; Number; pH; Sample ID; Site; Temperature, water; Titration; Type; water chemistry; δ13C, dissolved inorganic carbon; δ13CDIC; δ18O; δ18O, water; δ2H; δ Deuterium, water

Type: Dataset

Format: text/tab-separated-values, 1582 data points

Permalink

	Location	Call Number	Expected	Availability

Others were also interested in ...

DATA PANGAEA

S·F·X

Fulltext

2

Unknown

Hydrogeochemistry of submarine springs in Izola, Slovenia (2023)

Žvab Rožič, Petra ; Šušmelj, Kaja ; Vreča, Polona ; [et al.]

PANGAEA

add to mindlist on the mindlist

Details

Publication Date: 2023-07-25

Description: Not far from the coast of Izola, Slovenia, are twelve funnel-shaped depressions on the seabed containing springs of warm, sulphurous water. These submarine depressions with springs are divided into three groups: from east to west, Izola, Bele skale, and Ronek. Water with similar thermal and sulphuric properties also occurs in the terrestrial spring in Izola. Some of these submarine springs (M03 - Izola, M05 - Bele skale and M10, M11 - Ronek) and the terrestrial spring (K04) were sampled for hydrogeochemical study. Three sampling campaigns took place in June and July 2020, October 2020, and April 2021. In addition, samples of seawater (SW01, SW02, SW03), groundwater from a well (VK01) and local non-sulphuric springs (K01, K02, K03) were taken for comparison. The submarine spring water was sampled using 100-ml syringes. In April 2021, an 8-litre Niskin water sampler (OceanTest Equipment, Inc.) was used in addition to the syringes. Samples collected in April 2021 using two different methods are labeled with an additional letter: /B for syringes and /N for Niskin. In-situ physicochemical parameters - pH, temperature, electrical conductivity, oxidation-reduction potential, and dissolved oxygen - were measured in the samples from the seawater and the submarine springs using a digital Multi 3430 meter (WTW GmbH, Weilheim, Germany) as soon as they were brought aboard the boat. Measurements of the terrestrial waters were performed on site using the same digital meter. A total of 26 water samples were collected for further analysis. All water samples were collected in HDPE bottles, except those for isotopic composition of dissolved inorganic carbon, which was sampled directly to Labco glass ampoules after 0.45 µm pore-sized membrane filtration. The samples were then chemically treated where required and stored in a refrigerator until analysis. The samples were then prepared for further laboratory analysis: geochemical composition (cations, anions), isotopic composition of oxygen (δ¹⁸O) and hydrogen (δ²H), total alkalinity (TA), isotopic composition of dissolved inorganic carbon (δ¹³CDIC), tritium activity (³H), isotopic ratio of strontium (⁸⁷Sr/⁸⁶Sr), and isotopic composition of sulphur (δ³⁴Sₛ₀₄ ‰) and oxygen (δ¹⁸Oₛ₀₄ ‰) in sulphate. This database contains information on the sampling dates and basic characteristics of the sampling sites, as well as the results from field measurements and laboratory analyses.

Keywords: Alkalinity, total; Alkalinity, total, standard deviation; Aluminium; Antimony; Arsenic; Barium; Beryllium; Bismuth; Bromide; Cadmium; Caesium; Calcium; Cerium; Chloride; Chromium; Cobalt; Comment; Conductivity, electrical; Continuous flow isotope ratio mass spectrometer (CF-IRMS), Sercon, Europa Scientific 20-20, ANCA-TG preparation module; Copper; Date/Time of event; Dual inlet-isotope-ratio mass spectrometer (DI-IRMS), Finnigan MAT GmbH, Finnigan MAT Delta plus; Dysprosium; Element analyser (EA), Costech and continuous flow isotope ratio mass spectrometer (CF-IRMS), ThermoQuest, Finnigan Delta PlusXL; Erbium; Europium; Event label; Fluoride; Gadolinium; Gallium; Germanium; Gran titration; according to Gieskes, 1974; with pH electrode, Mettler Toledo, AG 8603; Group; Hafnium; Holmium; hydrogeochemistry; Indium; Inductively coupled plasma - mass spectrometry (ICP-MS), PerkinElmer, Thermo icapQ; Ion Chromatograph, Thermo Fisher Scientific, Dionex DX-120; Iron; isotopic composition; Izola_K01_1; Izola_K01_2; Izola_K02_1; Izola_K02_2; Izola_K03_1; Izola_K03_2; Izola_K04_1; Izola_K04_2; Izola_K04_3; Izola_M03; Izola_M03/B; Izola_M03/N; Izola_M05_1; Izola_M05_2; Izola_M05/B; Izola_M05/N; Izola_M10; Izola_M11; Izola_M11/B; Izola_M11/N; Izola_SW01; Izola_SW02; Izola_SW03; Izola_SW04; Izola_VK01_1; Izola_VK01_2; karst aquifer; Lanthanum; Latitude of event; Lead; Liquid Scintillation Counting- Guard Compensation Technology (LSC-GCT), PerkinElmer, Quantulus GCT 6220 [Super Low Level LSC]; Lithium; Longitude of event; Lutetium; Magnesium; Manganese; Mercury; Molybdenum; Multi-collector ICP-MS (MC-ICP-MS), Ametek, Nu Plasma II; Multi-parameter meter, Xylem Analytics, Multi 3430; Neodymium; Nickel; Niobium; Nitrate; Nitrite; Oxidation reduction (RedOx) potential; Oxygen, dissolved; pH; Phosphate; Potassium; Praseodymium; Rubidium; Samarium; Sample code/label; Sample ID; Sample method; Scandium; Selenium; Silicon; Silver; Site; Slovenia; Sodium; Strontium; Strontium-87/Strontium-86 ratio; Strontium-87/Strontium-86 ratio, standard deviation; submarine springs; Sulfate; Sulfur; Tantalum; Tellurium; Temperature, water; Terbium; Thallium; Thermal Combustion Elemental Analyzer (TCEA), Thermo Finnigan and continuous flow isotope ratio mass spectrometer (CF-IRMS), Thermo Electron, Delta V; Thorium; Thulium; Tin; Titanium; Tritium; Tritium, standard deviation; Tungsten; Type; Uranium; Vanadium; Water sample; WS; Ytterbium; Yttrium; Zinc; Zirconium; δ13C, dissolved inorganic carbon; δ13C, dissolved inorganic carbon, standard deviation; δ18O, sulfate; δ18O, sulfate, standard deviation; δ18O, water; δ18O, water, standard deviation; δ34S, sulfate; δ34S, sulfate, standard deviation; δ Deuterium, water; δ Deuterium, water, standard deviation

Type: Dataset

Format: text/tab-separated-values, 2307 data points

Permalink

	Location	Call Number	Expected	Availability

Others were also interested in ...

DATA PANGAEA

S·F·X

Fulltext

3

Unknown

Hydrogeochemical and isotopic data of the Učja aquifer, NW Slovenia (2024)

Žvab Rožič, Petra ; Grkman, Ana ; Vreča, Polona ; [et al.]

PANGAEA

add to mindlist on the mindlist

Details

Publication Date: 2024-01-30

Description: The Učja aquifer, located in the E-W-orientated Učja Valley in NW Slovenia, presents a potential cross-border water resource. Due to the difficult access and steep mountain morphology and complex structural conditions, only basic geological research was done. Despite the fact that the groundwater is already used as a source of drinking water (public and local supply), comprehensive analysis of the aquifer has not yet been carried out. Water for geochemical and isotopic analysis was sampled at 13 locations in the Učja Valley; groundwater was sampled at 12 locations, and the surface water (Učja River) at one location. The sampling sites were located at different elevations and due to accessibility practically all of them were on the southern slopes of the valley. Water measurements, sampling, and analysis were carried out from December 2017 to March 2019. Physico-chemical parameters (pH, temperature, electrical conductivity, oxidation-reduction potential, and dissolved oxygen) were measured on a monthly basis and in-situ at sampling sites using a digital Multimeter 3430 (WTW GmbH, Weilheim, Germany). The missing measurements from some sampling sites are the result of the springs running dry at the time of sampling. Water samples for further geochemical (cations and anions) and isotopic analysis were collected in HDPE bottles for isotopic composition of oxygen (δ¹⁸O), hydrogen (δ²H), total alkalinity (TA), tritium activity (³H), and in Labco glass ampoules for isotopic composition of dissolved inorganic carbon (δ¹³CDIC). Water samples for cations and δ¹³CDIC were filtered using a 0.45 μm pore-sized membrane, and for some analyses water was also chemically treated and stored in a refrigerator until they were analysed. A total of 22 water samples were collected for geochemical analyses (cations, anions), 37 water samples (seasonally) for isotopic analyses δ¹⁸O, δ²H, total alkalinity and δ¹³CDIC, and 10 water samples for ³H. The database comprises information on sampling sites, sampling dates, and the results of field measurements and laboratory analyses.

Keywords: Alkalinity, total; Alkalinity, total, standard deviation; ALTITUDE; Aluminium; Antimony; Arsenic; Barium; Beryllium; Bismuth; Bromide; Cadmium; Caesium; Calcium; Cerium; Chloride; Chromium; Cobalt; Comment; Conductivity, electrical; Continuous flow isotope ratio mass spectrometer (CF-IRMS), Sercon, Europa Scientific 20-20, ANCA-TG preparation module; Copper; cross-border karst aquifer; Date; Dual inlet-isotope-ratio mass spectrometer (DI-IRMS), Finnigan MAT GmbH, Finnigan MAT Delta plus; Dysprosium; Erbium; Europium; Event label; Fluoride; Gallium; Germanium; Gran titration; according to Gieskes, 1974; with pH electrode, Mettler Toledo, AG 8603; groundwater; Hafnium; Holmium; hydrogeochemistry; Indium; Inductively coupled plasma - mass spectrometry (ICP-MS), PerkinElmer, Thermo icapQ; Ion Chromatograph, Thermo Fisher Scientific, Dionex DX-120; Iron; isotopic composition; Lanthanum; LATITUDE; Lead; Liquid Scintillation Counting- Guard Compensation Technology (LSC-GCT), PerkinElmer, Quantulus GCT 6220 [Super Low Level LSC]; Lithium; LONGITUDE; Lutetium; Magnesium; Manganese; Mercury; Molybdenum; Multi-parameter meter, Xylem Analytics, Multi 3430; Neodymium; Nickel; Niobium; Nitrate; Nitrite; Oxidation reduction (RedOx) potential; Oxygen, dissolved; pH; Phosphate; Potassium; Praseodymium; Rubidium; Samarium; Sample code/label; Sample ID; Sample method; Scandium; Selenium; Silicon; Silver; Slovenia; Sodium; Strontium; Sulfate; Tantalum; Tellurium; Temperature, water; Terbium; Thallium; Thorium; Thulium; Tin; Titanium; Tritium; Tritium, standard deviation; Tungsten; Type; Ucja_UC1_1; Ucja_UC1_10; Ucja_UC1_11; Ucja_UC1_12; Ucja_UC1_2; Ucja_UC1_3; Ucja_UC1_4; Ucja_UC1_5; Ucja_UC1_6; Ucja_UC1_7; Ucja_UC1_8; Ucja_UC1_9; Ucja_UC10_1; Ucja_UC10_2; Ucja_UC10_3; Ucja_UC10_4; Ucja_UC10_5; Ucja_UC11_10; Ucja_UC11_11; Ucja_UC11_12; Ucja_UC11_2; Ucja_UC11_3; Ucja_UC11_4; Ucja_UC11_5; Ucja_UC11_6; Ucja_UC12_10; Ucja_UC12_11; Ucja_UC12_12; Ucja_UC12_2; Ucja_UC12_3; Ucja_UC12_4; Ucja_UC12_5; Ucja_UC12_6; Ucja_UC12_9; Ucja_UC13_6; Ucja_UC2_1; Ucja_UC2_10; Ucja_UC2_11; Ucja_UC2_12; Ucja_UC2_2; Ucja_UC2_3; Ucja_UC2_4; Ucja_UC2_5; Ucja_UC2_6; Ucja_UC3_1; Ucja_UC3_10; Ucja_UC3_11; Ucja_UC3_12; Ucja_UC3_2; Ucja_UC3_3; Ucja_UC3_4; Ucja_UC3_5; Ucja_UC3_6; Ucja_UC3_7; Ucja_UC3_8; Ucja_UC3_9; Ucja_UC4_1; Ucja_UC4_10; Ucja_UC4_11; Ucja_UC4_12; Ucja_UC4_2; Ucja_UC4_3; Ucja_UC4_4; Ucja_UC4_5; Ucja_UC4_6; Ucja_UC4_7; Ucja_UC4_8; Ucja_UC4_9; Ucja_UC5_1; Ucja_UC5_10; Ucja_UC5_11; Ucja_UC5_12; Ucja_UC5_2; Ucja_UC5_3; Ucja_UC5_4; Ucja_UC5_5; Ucja_UC5_6; Ucja_UC5_7; Ucja_UC5_8; Ucja_UC5_9; Ucja_UC6_1; Ucja_UC6_10; Ucja_UC6_11; Ucja_UC6_12; Ucja_UC6_2; Ucja_UC6_3; Ucja_UC6_4; Ucja_UC6_5; Ucja_UC6_6; Ucja_UC6_7; Ucja_UC6_8; Ucja_UC6_9; Ucja_UC7_1; Ucja_UC7_10; Ucja_UC7_11; Ucja_UC7_12; Ucja_UC7_2; Ucja_UC7_3; Ucja_UC7_4; Ucja_UC7_5; Ucja_UC7_6; Ucja_UC7_7; Ucja_UC7_8; Ucja_UC7_9; Ucja_UC8_1; Ucja_UC8_10; Ucja_UC8_11; Ucja_UC8_12; Ucja_UC8_2; Ucja_UC8_3; Ucja_UC8_4; Ucja_UC8_5; Ucja_UC8_6; Ucja_UC8_7; Ucja_UC8_8; Ucja_UC8_9; Ucja_UC9_1; Ucja_UC9_10; Ucja_UC9_11; Ucja_UC9_12; Ucja_UC9_2; Ucja_UC9_3; Ucja_UC9_4; Ucja_UC9_5; Ucja_UC9_6; Ucja_UC9_7; Ucja_UC9_8; Ucja_UC9_9; Uranium; Vanadium; Water sample; WS; Ytterbium; Yttrium; Zinc; Zirconium; δ13C, dissolved inorganic carbon; δ13C, dissolved inorganic carbon, standard deviation; δ18O, water; δ18O, water, standard deviation; δ Deuterium, water; δ Deuterium, water, standard deviation

Type: Dataset

Format: text/tab-separated-values, 3448 data points

Permalink