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  • 2020-2024  (24)
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  • 1
    facet.materialart.
    Unknown
    Drought Conditions Enhance Groundwater Table Fluctuations Caused by Hydropower Plant Management (2022)
    Details
    Publication Date: 2023-01-13
    Description: Management of hydropower plants strongly influences streamflow dynamics and hence the interaction between surface water and groundwater. As dam operations cause variations in river stages, these can result in changes in the groundwater level at multiple temporal scales. In this work, we study the case of an Alpine aquifer, where weekly fluctuations are particularly pronounced. We consider an area with four river reaches differently impacted by reservoir operations and investigate the influence of these rivers on the common aquifer. Using continuous wavelet transform and wavelet coherence analysis, we show that weekly fluctuations in the groundwater table are particularly pronounced in dry years, in particular in the winter season, although the area of the aquifer impacted by dam operations remains almost unchanged. We thus observe that in Alpine catchments, surface water‐groundwater interaction is sensitive to the conditions determined by a specific hydrological year. We also investigate the influences of the river‐aquifer water fluxes and show that under dry conditions hydropeaking mainly affects their temporal dynamics. Our observations have significant consequences for predicting nutrient and temperature dynamics/regimes in river‐aquifer systems impacted by hydropower plant management.
    Description: Plain Language Summary: The operation of hydropower plants affects the water level in the downstream part of the river, which in turn can alter the groundwater level. In this work, we study an Alpine aquifer crossed by rivers differently impacted by hydropower production. We use statistical tools to analyze the interaction between the rivers and the groundwater, and observe that this interaction is sensitive to the conditions of the hydrological year, such as dry periods.
    Description: Key Points: Wavelet power spectrum and coherence analysis is used to study river‐aquifer interactions under dam operations in an Alpine catchment. The impact of reservoir operations on the aquifer is strongest under low flow conditions but the area impacted shows little variation. Under low flow conditions, dam operations considerably influence the frequency of the water exchange between rivers and aquifer.
    Description: Consejo Nacional de Ciencia y Tecnología http://dx.doi.org/10.13039/501100003141
    Description: Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659
    Description: Consejo Veracruzano de Investigación Científica y Desarrollo Tecnológico
    Description: https://doi.org/10.17632/97jchhz4s8.2
    Keywords: ddc:551 ; surface water‐groundwater interaction ; hydropower ; managed rivers ; groundwater modeling
    Language: English
    Type: doc-type:article
    Location Call Number Expected Availability
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    CITATION GEO-LEO
  • 2
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    Unknown
    Frictional power dissipation in a seismic ancient fault (2024)
    Elsevier
    Details
    Publication Date: 2024-03-20
    Description: The frictional power per unit area (product of frictional traction τ and slip rate in MW m−2) dissipated during earthquakes triggers fault dynamic weakening mechanisms that control rupture nucleation, propagation and arrest. Although of great relevance in earthquake mechanics, cannot, with rare exceptions, be determined by geophysical methods. Here we exploit theoretical, experimental and geological constraints to estimate dissipated on a fault patch exhumed from 7-9 km depth. According to theoretical models, in polymineralic, silicate rocks the amplitude (〈 1 mm) of the grain-scale roughness of the boundary between frictional melt (pseudotachylyte) and host rock decreases with increasing . The dependence of grain-scale roughness with is due to differential melt front migration in the host rock minerals. This dependence is confirmed by friction experiments reproducing seismic slip where pseudotachylytes were produced by shearing tonalite at ranging from 5 to 25 MW m−2. In natural pseudotachylytes across tonalites, the grain-scale roughness broadly decreases from extensional to compressional fault domains where lower and higher are expected, respectively. Analysis of the natural dataset calibrated by experiments yields values in the range of 4-60 MW m−2 (16 MW m−2 average value). These values, estimated in small fault patches, are at the lower end of broad estimates of (3-300 MW m−2) obtained from frictional tractions (30-300 MPa) and fault slip rates (0.1-1 m/s) assumed as typical of upper crustal earthquakes.
    Description: Published
    Description: 118057
    Description: OST3 Vicino alla faglia
    Description: JCR Journal
    Repository Name: Istituto Nazionale di Geofisica e Vulcanologia (INGV)
    Type: article
    Location Call Number Expected Availability
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    PAPER (OA)
  • 3
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    Unknown
    The HYPERMAQ dataset (2022)
    PANGAEA
    Details
    Publication Date: 2023-06-24
    Description: The HYPERMAQ dataset contributes to a better description of marine optics in optically complex water bodies by providing optical and biogeochemical parameters for 180 sampling stations with turbidity and chlorophyll-a concentration ranging between 1 to 700 FNU and between 0.9 to 180 mg m-3 respectively. The HYPERMAQ dataset is composed of biogeochemical parameters (i.e. turbidity, suspended particulate matter, chlorophyll-a and other phytoplankton pigments concentrations), apparent optical properties (i.e. water reflectance from above water measurements) and inherent optical properties (i.e. absorption and attenuation coefficients) from six different study areas. These study areas include large estuaries (i.e. the Rio de la Plata in Argentina, the Yangtze Estuary in China and the Gironde Estuary in France), inland waters (i.e. the Spuikom in Belgium and Chascomus Lake in Argentina) and coastal waters (Belgium). All data were collected between April and September 2018.
    Keywords: chlorophyll-a concentration; HYPERMAQ; Hyperspectral and multi-mission high resolution optical remote sensing of aquatic environments; inherent optical properties; LifeWatch_BE; LifeWatch BE; optically complex waters; radiometry; Suspended particulate matter; turbidity; water reflectance
    Type: Dataset
    Format: application/zip, 11 datasets
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 4
    facet.materialart.
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    Water reflectance standard deviation from six different study areas (in Argentina, China, France and Belgium) measured with TRiOS (2022)
    PANGAEA
    Details
    Publication Date: 2023-08-07
    Keywords: BELGIUM_WATERS_APRIL2018; BELGIUM_WATERS_APRIL2018_ST130; BELGIUM_WATERS_APRIL2018_ST215; BELGIUM_WATERS_APRIL2018_ST230; BELGIUM_WATERS_APRIL2018_ST330; BELGIUM_WATERS_APRIL2018_ST700; BELGIUM_WATERS_APRIL2018_ST710; BELGIUM_WATERS_APRIL2018_ST780; BELGIUM_WATERS_APRIL2018_W07BIS; BELGIUM_WATERS_JULY2018; BELGIUM_WATERS_JULY2018_LW_120; BELGIUM_WATERS_JULY2018_LW_130; BELGIUM_WATERS_JULY2018_LW_215; BELGIUM_WATERS_JULY2018_LW_230; BELGIUM_WATERS_JULY2018_LW_330; BELGIUM_WATERS_JULY2018_LW_700; BELGIUM_WATERS_JULY2018_LW_710; BELGIUM_WATERS_JULY2018_LW_780; BELGIUM_WATERS_JULY2018_LW_Harbour; BELGIUM_WATERS_JULY2018_LW_ZG02; Campaign; CHASCOMUS; CHASCOMUS_C01; CHASCOMUS_C02; CHASCOMUS_C03; CHASCOMUS_C04; CHASCOMUS_C05; chlorophyll-a concentration; DATE/TIME; DEPTH, water; Event label; HYP_0001; HYP_0002; HYP_0003; HYP_0004; HYP_0005; HYP_0006; HYP_0007; HYP_0008; HYP_0010; HYP_0011; HYP_0012; HYP_0013; HYP_0014; HYP_0015; HYP_0016; HYP_0017; HYP_0018; HYP_0019; HYP_0020; HYP_0021; HYP_0022; HYP_0023; HYP_0024; HYP_0081; HYP_0082; HYP_0083; HYP_0084; HYP_0085; HYP_0086; HYP_0087; HYP_0088; HYP_0089; HYP_0090; HYP_0091; HYP_0094; HYP_0095; HYP_0096; HYP_0097; HYP_0098; HYP_0099; HYP_0100; HYP_0101; HYP_0102; HYP_0103; HYP_0104; HYP_0105; HYP_0106; HYP_0107; HYP_0108; HYP_0109; HYP_0110; HYP_0111; HYP_0112; HYP_0113; HYP_0114; HYP_0115; HYP_0117; HYP_0118; HYP_0119; HYP_0120; HYP_0121; HYP_0122; HYP_0123; HYP_0124; HYP_0125; HYP_0126; HYP_0127; HYP_0128; HYP_0129; HYP_0130; HYP_0131; HYP_0132; HYP_0133; HYP_0134; HYP_0135; HYP_0136; HYP_0137; HYP_0138; HYP_0139; HYP_0140; HYP_0141; HYP_0142; HYP_0143; HYP_0144; HYP_0145; HYP_0146; HYP_0153; HYP_0155; HYP_0157; HYP_0158; HYP_0159; HYP_0160; HYP_0161; HYP_0162; HYP_0163; HYP_0164; HYP_0165; HYP_0166; HYP_0167; HYP_0168; HYP_0169; HYP_0170; HYP_0171; HYP_0172; HYP_0173; HYP_0174; HYP_0175; HYP_0176; HYP_0177; HYP_0178; HYP_0179; HYPERMAQ; Hyperspectral and multi-mission high resolution optical remote sensing of aquatic environments; Identification; inherent optical properties; LATITUDE; LE_VERDON; LE_VERDON_GG14; LE_VERDON_GG15; LE_VERDON_GG16; LE_VERDON_GG17; LE_VERDON_GG18; LE_VERDON_GG19; LE_VERDON_GG20; LE_VERDON_GG21; LE_VERDON_GG22; LE_VERDON_GG23; LE_VERDON_GG24; LE_VERDON_GG41; LE_VERDON_GG42; LE_VERDON_GG43; LE_VERDON_GG44; LE_VERDON_GG45; LE_VERDON_GG46; LE_VERDON_GG47; LE_VERDON_GG48; LE_VERDON_GG49; LE_VERDON_GG50; LE_VERDON_GG51; LifeWatch_BE; LifeWatch BE; LONGITUDE; MULT; Multiple investigations; optically complex waters; PAUILLAC; PAUILLAC_GG01; PAUILLAC_GG02; PAUILLAC_GG03; PAUILLAC_GG04; PAUILLAC_GG05; PAUILLAC_GG06; PAUILLAC_GG07; PAUILLAC_GG08; PAUILLAC_GG09; PAUILLAC_GG10; PAUILLAC_GG11; PAUILLAC_GG25; PAUILLAC_GG26; PAUILLAC_GG27; PAUILLAC_GG28; PAUILLAC_GG29; PAUILLAC_GG30; PAUILLAC_GG31; PAUILLAC_GG32; PAUILLAC_GG33; PAUILLAC_GG34; PAUILLAC_GG35; PAUILLAC_GG36; PAUILLAC_GG37; PAUILLAC_GG38; Radiometer, TriOS; radiometry; RIO_DE_LA_PLATA; RIO_DE_LA_PLATA_P01; RIO_DE_LA_PLATA_P02; RIO_DE_LA_PLATA_P03; RIO_DE_LA_PLATA_P04; RIO_DE_LA_PLATA_P05; RIO_DE_LA_PLATA_P06; RIO_DE_LA_PLATA_P07; RIO_DE_LA_PLATA_P08; RIO_DE_LA_PLATA_P09; RIO_DE_LA_PLATA_P10; RIO_DE_LA_PLATA_P11; RIO_DE_LA_PLATA_P12; RIO_DE_LA_PLATA_P13; RIO_DE_LA_PLATA_P14; RIO_DE_LA_PLATA_P15; RIO_DE_LA_PLATA_P16; Rubber boat; Sampling on land; Simon Stevin; SPUIKOM_APRIL2018; SPUIKOM_APRIL2018_SP38; SPUIKOM_APRIL2018_SP39b; SPUIKOM_APRIL2018_SP40b; SPUIKOM_APRIL2018_SP41; SPUIKOM_APRIL2018_SP42; SPUIKOM_APRIL2018_SP43; SPUIKOM_APRIL2018_SP44; SPUIKOM_JULY2018; SPUIKOM_JULY2018_SP50; SPUIKOM_JULY2018_SP51; SPUIKOM_JULY2018_SP52; SPUIKOM_JULY2018_SP53; SPUIKOM_JULY2018_SP54; SPUIKOM_JULY2018_SP55; SPUIKOM_JULY2018_SP56; SPUIKOM_JULY2018_SP57; SPUIKOM_JULY2018_SP58; SPUIKOM_JULY2018_SP59; SPUIKOM_JULY2018_SP60; SPUIKOM_JULY2018_SP62; SPUIKOM_JULY2018_SP63; SPUIKOM_JULY2018_SP64; SPUIKOM_JULY2018_SP65; SPUIKOM_JULY2018_SP66; SPUIKOM_JULY2018_SP67; SPUIKOM_JULY2018_SP68; Station label; Suspended particulate matter; turbidity; water reflectance; Water reflectance at 350 nm, standard deviation; Water reflectance at 352.5 nm, standard deviation; Water reflectance at 355 nm, standard deviation; Water reflectance at 357.5 nm, standard deviation; Water reflectance at 360 nm, standard deviation; Water reflectance at 362.5 nm, standard deviation; Water reflectance at 365 nm, standard deviation; Water reflectance at 367.5 nm, standard deviation; Water reflectance at 370 nm, standard deviation; Water reflectance at 372.5 nm, standard deviation; Water reflectance at 375 nm, standard deviation; Water reflectance at 377.5 nm, standard deviation; Water reflectance at 380 nm, standard deviation; Water reflectance at 382.5 nm, standard deviation; Water reflectance at 385 nm, standard deviation; Water reflectance at 387.5 nm, standard deviation; Water reflectance at 390 nm, standard deviation; Water reflectance at 392.5 nm, standard deviation; Water reflectance at 395 nm, standard deviation; Water reflectance at 397.5 nm, standard deviation; Water reflectance at 400 nm, standard deviation; Water reflectance at 402.5 nm, standard deviation; Water reflectance at 405 nm, standard deviation; Water reflectance at 407.5 nm, standard deviation; Water reflectance at 410 nm, standard deviation; Water reflectance at 412.5 nm, standard deviation; Water reflectance at 415 nm, standard deviation; Water reflectance at 417.5 nm, standard deviation; Water reflectance at 420 nm, standard deviation; Water reflectance at 422.5 nm, standard deviation; Water reflectance at 425 nm, standard deviation; Water reflectance at 427.5 nm, standard deviation; Water reflectance at 430 nm, standard deviation; Water reflectance at 432.5 nm, standard deviation; Water reflectance at 435 nm, standard deviation; Water reflectance at 437.5 nm, standard deviation; Water reflectance at 440 nm, standard deviation; Water reflectance at 442.5 nm, standard deviation; Water reflectance at 445 nm, standard deviation; Water reflectance at 447.5 nm, standard deviation; Water reflectance at 450 nm, standard deviation; Water reflectance at 452.5 nm, standard deviation; Water reflectance at 455 nm, standard deviation; Water reflectance at 457.5 nm, standard deviation; Water reflectance at 460 nm, standard deviation; Water reflectance at 462.5 nm, standard deviation; Water reflectance at 465 nm, standard deviation; Water reflectance at 467.5 nm, standard deviation; Water reflectance at 470 nm, standard deviation; Water reflectance at 472.5 nm, standard deviation; Water reflectance at 475 nm, standard deviation; Water reflectance at 477.5 nm, standard deviation; Water reflectance at 480 nm, standard deviation; Water reflectance at 482.5 nm, standard deviation; Water reflectance at 485 nm, standard deviation; Water reflectance at 487.5 nm, standard deviation; Water reflectance at 490 nm, standard deviation; Water reflectance at 492.5 nm, standard deviation; Water reflectance at 495 nm, standard deviation; Water reflectance at 497.5 nm, standard deviation; Water reflectance at 500 nm, standard deviation; Water reflectance at 502.5 nm, standard deviation; Water reflectance at 505 nm, standard deviation; Water reflectance at 507.5 nm, standard deviation; Water reflectance at 510 nm, standard deviation; Water reflectance at 512.5 nm, standard deviation; Water reflectance at 515 nm, standard deviation; Water reflectance at 517.5 nm, standard deviation; Water reflectance at 520 nm, standard deviation; Water reflectance at 522.5 nm, standard deviation; Water reflectance at 525 nm, standard deviation; Water reflectance at 527.5 nm, standard deviation; Water reflectance at 530 nm, standard deviation; Water reflectance at 532.5 nm, standard deviation; Water reflectance at 535 nm, standard deviation; Water reflectance at 537.5 nm, standard deviation; Water reflectance at 540 nm, standard deviation; Water reflectance at 542.5 nm, standard deviation; Water reflectance at 545 nm, standard deviation; Water
    Type: Dataset
    Format: text/tab-separated-values, 20223 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 5
    facet.materialart.
    Unknown
    Spectral downwelling irradiance from six different study areas (in Argentina, China, France and Belgium) measured with TRiOS (2022)
    PANGAEA
    Details
    Publication Date: 2023-08-07
    Keywords: BELGIUM_WATERS_APRIL2018; BELGIUM_WATERS_APRIL2018_ST130; BELGIUM_WATERS_APRIL2018_ST215; BELGIUM_WATERS_APRIL2018_ST230; BELGIUM_WATERS_APRIL2018_ST330; BELGIUM_WATERS_APRIL2018_ST700; BELGIUM_WATERS_APRIL2018_ST710; BELGIUM_WATERS_APRIL2018_ST780; BELGIUM_WATERS_APRIL2018_W07BIS; BELGIUM_WATERS_JULY2018; BELGIUM_WATERS_JULY2018_LW_120; BELGIUM_WATERS_JULY2018_LW_130; BELGIUM_WATERS_JULY2018_LW_215; BELGIUM_WATERS_JULY2018_LW_230; BELGIUM_WATERS_JULY2018_LW_330; BELGIUM_WATERS_JULY2018_LW_700; BELGIUM_WATERS_JULY2018_LW_710; BELGIUM_WATERS_JULY2018_LW_780; BELGIUM_WATERS_JULY2018_LW_Harbour; BELGIUM_WATERS_JULY2018_LW_ZG02; Campaign; CHASCOMUS; CHASCOMUS_C01; CHASCOMUS_C02; CHASCOMUS_C03; CHASCOMUS_C04; CHASCOMUS_C05; chlorophyll-a concentration; DATE/TIME; Event label; HYP_0001; HYP_0002; HYP_0003; HYP_0004; HYP_0005; HYP_0006; HYP_0007; HYP_0008; HYP_0010; HYP_0011; HYP_0012; HYP_0013; HYP_0014; HYP_0015; HYP_0016; HYP_0017; HYP_0018; HYP_0019; HYP_0020; HYP_0021; HYP_0022; HYP_0023; HYP_0024; HYP_0081; HYP_0082; HYP_0083; HYP_0084; HYP_0085; HYP_0086; HYP_0087; HYP_0088; HYP_0089; HYP_0090; HYP_0091; HYP_0094; HYP_0095; HYP_0096; HYP_0097; HYP_0098; HYP_0099; HYP_0100; HYP_0101; HYP_0102; HYP_0103; HYP_0104; HYP_0105; HYP_0106; HYP_0107; HYP_0108; HYP_0109; HYP_0110; HYP_0111; HYP_0112; HYP_0113; HYP_0114; HYP_0115; HYP_0117; HYP_0118; HYP_0119; HYP_0120; HYP_0121; HYP_0122; HYP_0123; HYP_0124; HYP_0125; HYP_0126; HYP_0127; HYP_0128; HYP_0129; HYP_0130; HYP_0131; HYP_0132; HYP_0133; HYP_0134; HYP_0135; HYP_0136; HYP_0137; HYP_0138; HYP_0139; HYP_0140; HYP_0141; HYP_0142; HYP_0143; HYP_0144; HYP_0145; HYP_0146; HYP_0153; HYP_0155; HYP_0157; HYP_0158; HYP_0159; HYP_0160; HYP_0161; HYP_0162; HYP_0163; HYP_0164; HYP_0165; HYP_0166; HYP_0167; HYP_0168; HYP_0169; HYP_0170; HYP_0171; HYP_0172; HYP_0173; HYP_0174; HYP_0175; HYP_0176; HYP_0177; HYP_0178; HYP_0179; HYPERMAQ; Hyperspectral and multi-mission high resolution optical remote sensing of aquatic environments; Identification; inherent optical properties; LATITUDE; LE_VERDON; LE_VERDON_GG14; LE_VERDON_GG15; LE_VERDON_GG16; LE_VERDON_GG17; LE_VERDON_GG18; LE_VERDON_GG19; LE_VERDON_GG20; LE_VERDON_GG21; LE_VERDON_GG22; LE_VERDON_GG23; LE_VERDON_GG24; LE_VERDON_GG41; LE_VERDON_GG42; LE_VERDON_GG43; LE_VERDON_GG44; LE_VERDON_GG45; LE_VERDON_GG46; LE_VERDON_GG47; LE_VERDON_GG48; LE_VERDON_GG49; LE_VERDON_GG50; LE_VERDON_GG51; LifeWatch_BE; LifeWatch BE; LONGITUDE; MULT; Multiple investigations; optically complex waters; PAUILLAC; PAUILLAC_GG01; PAUILLAC_GG02; PAUILLAC_GG03; PAUILLAC_GG04; PAUILLAC_GG05; PAUILLAC_GG06; PAUILLAC_GG07; PAUILLAC_GG08; PAUILLAC_GG09; PAUILLAC_GG10; PAUILLAC_GG11; PAUILLAC_GG25; PAUILLAC_GG26; PAUILLAC_GG27; PAUILLAC_GG28; PAUILLAC_GG29; PAUILLAC_GG30; PAUILLAC_GG31; PAUILLAC_GG32; PAUILLAC_GG33; PAUILLAC_GG34; PAUILLAC_GG35; PAUILLAC_GG36; PAUILLAC_GG37; PAUILLAC_GG38; Radiometer, TriOS; radiometry; RIO_DE_LA_PLATA; RIO_DE_LA_PLATA_P01; RIO_DE_LA_PLATA_P02; RIO_DE_LA_PLATA_P03; RIO_DE_LA_PLATA_P04; RIO_DE_LA_PLATA_P05; RIO_DE_LA_PLATA_P06; RIO_DE_LA_PLATA_P07; RIO_DE_LA_PLATA_P08; RIO_DE_LA_PLATA_P09; RIO_DE_LA_PLATA_P10; RIO_DE_LA_PLATA_P11; RIO_DE_LA_PLATA_P12; RIO_DE_LA_PLATA_P13; RIO_DE_LA_PLATA_P14; RIO_DE_LA_PLATA_P15; RIO_DE_LA_PLATA_P16; Rubber boat; Sampling on land; Simon Stevin; Spectral irradiance, downward at 350 nm; Spectral irradiance, downward at 352.5 nm; Spectral irradiance, downward at 355 nm; Spectral irradiance, downward at 357.5 nm; Spectral irradiance, downward at 360 nm; Spectral irradiance, downward at 362.5 nm; Spectral irradiance, downward at 365 nm; Spectral irradiance, downward at 367.5 nm; Spectral irradiance, downward at 370 nm; Spectral irradiance, downward at 372.5 nm; Spectral irradiance, downward at 375 nm; Spectral irradiance, downward at 377.5 nm; Spectral irradiance, downward at 380 nm; Spectral irradiance, downward at 382.5 nm; Spectral irradiance, downward at 385 nm; Spectral irradiance, downward at 387.5 nm; Spectral irradiance, downward at 390 nm; Spectral irradiance, downward at 392.5 nm; Spectral irradiance, downward at 395 nm; Spectral irradiance, downward at 397.5 nm; Spectral irradiance, downward at 400 nm; Spectral irradiance, downward at 402.5 nm; Spectral irradiance, downward at 405 nm; Spectral irradiance, downward at 407.5 nm; Spectral irradiance, downward at 410 nm; Spectral irradiance, downward at 412.5 nm; Spectral irradiance, downward at 415 nm; Spectral irradiance, downward at 417.5 nm; Spectral irradiance, downward at 420 nm; Spectral irradiance, downward at 422.5 nm; Spectral irradiance, downward at 425 nm; Spectral irradiance, downward at 427.5 nm; Spectral irradiance, downward at 430 nm; Spectral irradiance, downward at 432.5 nm; Spectral irradiance, downward at 435 nm; Spectral irradiance, downward at 437.5 nm; Spectral irradiance, downward at 440 nm; Spectral irradiance, downward at 442.5 nm; Spectral irradiance, downward at 445 nm; Spectral irradiance, downward at 447.5 nm; Spectral irradiance, downward at 450 nm; Spectral irradiance, downward at 452.5 nm; Spectral irradiance, downward at 455 nm; Spectral irradiance, downward at 457.5 nm; Spectral irradiance, downward at 460 nm; Spectral irradiance, downward at 462.5 nm; Spectral irradiance, downward at 465 nm; Spectral irradiance, downward at 467.5 nm; Spectral irradiance, downward at 470 nm; Spectral irradiance, downward at 472.5 nm; Spectral irradiance, downward at 475 nm; Spectral irradiance, downward at 477.5 nm; Spectral irradiance, downward at 480 nm; Spectral irradiance, downward at 482.5 nm; Spectral irradiance, downward at 485 nm; Spectral irradiance, downward at 487.5 nm; Spectral irradiance, downward at 490 nm; Spectral irradiance, downward at 492.5 nm; Spectral irradiance, downward at 495 nm; Spectral irradiance, downward at 497.5 nm; Spectral irradiance, downward at 500 nm; Spectral irradiance, downward at 502.5 nm; Spectral irradiance, downward at 505 nm; Spectral irradiance, downward at 507.5 nm; Spectral irradiance, downward at 510 nm; Spectral irradiance, downward at 512.5 nm; Spectral irradiance, downward at 515 nm; Spectral irradiance, downward at 517.5 nm; Spectral irradiance, downward at 520 nm; Spectral irradiance, downward at 522.5 nm; Spectral irradiance, downward at 525 nm; Spectral irradiance, downward at 527.5 nm; Spectral irradiance, downward at 530 nm; Spectral irradiance, downward at 532.5 nm; Spectral irradiance, downward at 535 nm; Spectral irradiance, downward at 537.5 nm; Spectral irradiance, downward at 540 nm; Spectral irradiance, downward at 542.5 nm; Spectral irradiance, downward at 545 nm; Spectral irradiance, downward at 547.5 nm; Spectral irradiance, downward at 550 nm; Spectral irradiance, downward at 552.5 nm; Spectral irradiance, downward at 555 nm; Spectral irradiance, downward at 557.5 nm; Spectral irradiance, downward at 560 nm; Spectral irradiance, downward at 562.5 nm; Spectral irradiance, downward at 565 nm; Spectral irradiance, downward at 567.5 nm; Spectral irradiance, downward at 570 nm; Spectral irradiance, downward at 572.5 nm; Spectral irradiance, downward at 575 nm; Spectral irradiance, downward at 577.5 nm; Spectral irradiance, downward at 580 nm; Spectral irradiance, downward at 582.5 nm; Spectral irradiance, downward at 585 nm; Spectral irradiance, downward at 587.5 nm; Spectral irradiance, downward at 590 nm; Spectral irradiance, downward at 592.5 nm; Spectral irradiance, downward at 595 nm; Spectral irradiance, downward at 597.5 nm; Spectral irradiance, downward at 600 nm; Spectral irradiance, downward at 602.5 nm; Spectral irradiance, downward at 605 nm; Spectral irradiance, downward at 607.5 nm; Spectral irradiance, downward at 610 nm; Spectral irradiance, downward at 612.5 nm; Spectral irradiance, downward at 615 nm; Spectral irradiance, downward at 617.5 nm; Spectral irradiance, downward at 620 nm; Spectral irradiance, downward at 622.5 nm; Spectral irradiance, downward at 625 nm; Spectral
    Type: Dataset
    Format: text/tab-separated-values, 24864 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 6
    facet.materialart.
    Unknown
    Measurements of turbidity, chlorophyll-a, suspended particulate matter and suspended particulate inorganic matter in six different study areas (in Argentina, China, France and Belgium) (2022)
    PANGAEA
    Details
    Publication Date: 2023-08-07
    Keywords: BAOZHEN; BAOZHEN_0604S1; BAOZHEN_0604S2; BAOZHEN_0604S3; BAOZHEN_0604S4; BAOZHEN_0604S5; BAOZHEN_0605S1; BAOZHEN_0605S2; BAOZHEN_0605S3; BAOZHEN_0605S4; BAOZHEN_0605S5; BAOZHEN_0605S6; BAOZHEN_0605S7; BAOZHEN_0605S8; BAOZHEN_0606S1; BAOZHEN_0606S2; BAOZHEN_0606S3; BAOZHEN_0606S4; BAOZHEN_0606S5; BAOZHEN_0606S6; BAOZHEN_0606S7; BAOZHEN_0606S8; BAOZHEN_0607S1; BAOZHEN_0607S2; BAOZHEN_0607S3; BAOZHEN_0607S4; BAOZHEN_0607S5; BAOZHEN_0607S6; BAOZHEN_0607S7; BAOZHEN_0607S8; BAOZHEN_0608S1; BAOZHEN_0608S2; BAOZHEN_0608S3; BAOZHEN_0608S4; BAOZHEN_0608S5; BAOZHEN_0608S6; BAOZHEN_0608S7; BAOZHEN_0608S8; BELGIUM_WATERS_APRIL2018; BELGIUM_WATERS_APRIL2018_ST130; BELGIUM_WATERS_APRIL2018_ST215; BELGIUM_WATERS_APRIL2018_ST230; BELGIUM_WATERS_APRIL2018_ST330; BELGIUM_WATERS_APRIL2018_ST700; BELGIUM_WATERS_APRIL2018_ST710; BELGIUM_WATERS_APRIL2018_ST780; BELGIUM_WATERS_APRIL2018_W07BIS; BELGIUM_WATERS_APRIL2018_ZG02; BELGIUM_WATERS_JULY2018; BELGIUM_WATERS_JULY2018_LW_120; BELGIUM_WATERS_JULY2018_LW_130; BELGIUM_WATERS_JULY2018_LW_215; BELGIUM_WATERS_JULY2018_LW_230; BELGIUM_WATERS_JULY2018_LW_330; BELGIUM_WATERS_JULY2018_LW_700; BELGIUM_WATERS_JULY2018_LW_710; BELGIUM_WATERS_JULY2018_LW_780; BELGIUM_WATERS_JULY2018_LW_Harbour; BELGIUM_WATERS_JULY2018_LW_ZG02; Campaign; CHASCOMUS; CHASCOMUS_C01; CHASCOMUS_C02; CHASCOMUS_C03; CHASCOMUS_C04; CHASCOMUS_C05; Chlorophyll a; chlorophyll-a concentration; CHONGXI; CHONGXI_0531S1; CHONGXI_0531S2; CHONGXI_0601S1; CHONGXI_0601S2; CHONGXI_0601S3; CHONGXI_0601S4; CHONGXI_0601S5; CHONGXI_0601S6; CHONGXI_0601S7; CHONGXI_0601S8; CHONGXI_0603S1; CHONGXI_0603S2; CHONGXI_0603S3; CHONGXI_0603S4; CHONGXI_0603S5; CHONGXI_0603S6; CHONGXI_0603S7; CHONGXI_0603S8; DATE/TIME; DEPTH, water; Event label; HYP_0001; HYP_0002; HYP_0003; HYP_0004; HYP_0005; HYP_0006; HYP_0007; HYP_0008; HYP_0009; HYP_0010; HYP_0011; HYP_0012; HYP_0013; HYP_0014; HYP_0015; HYP_0016; HYP_0017; HYP_0018; HYP_0019; HYP_0020; HYP_0021; HYP_0022; HYP_0023; HYP_0024; HYP_0025; HYP_0026; HYP_0027; HYP_0028; HYP_0029; HYP_0030; HYP_0031; HYP_0032; HYP_0033; HYP_0034; HYP_0035; HYP_0036; HYP_0037; HYP_0038; HYP_0039; HYP_0040; HYP_0041; HYP_0042; HYP_0043; HYP_0044; HYP_0045; HYP_0046; HYP_0047; HYP_0048; HYP_0049; HYP_0050; HYP_0051; HYP_0052; HYP_0053; HYP_0054; HYP_0055; HYP_0056; HYP_0057; HYP_0058; HYP_0059; HYP_0060; HYP_0061; HYP_0062; HYP_0063; HYP_0064; HYP_0065; HYP_0066; HYP_0067; HYP_0068; HYP_0069; HYP_0070; HYP_0071; HYP_0072; HYP_0073; HYP_0074; HYP_0075; HYP_0076; HYP_0077; HYP_0078; HYP_0079; HYP_0080; HYP_0081; HYP_0082; HYP_0083; HYP_0084; HYP_0085; HYP_0086; HYP_0087; HYP_0088; HYP_0089; HYP_0090; HYP_0091; HYP_0092; HYP_0093; HYP_0094; HYP_0095; HYP_0096; HYP_0097; HYP_0098; HYP_0099; HYP_0100; HYP_0101; HYP_0102; HYP_0103; HYP_0104; HYP_0105; HYP_0106; HYP_0107; HYP_0108; HYP_0109; HYP_0110; HYP_0111; HYP_0112; HYP_0113; HYP_0114; HYP_0115; HYP_0116; HYP_0117; HYP_0118; HYP_0119; HYP_0120; HYP_0121; HYP_0122; HYP_0123; HYP_0124; HYP_0125; HYP_0126; HYP_0127; HYP_0128; HYP_0129; HYP_0130; HYP_0131; HYP_0132; HYP_0133; HYP_0134; HYP_0135; HYP_0136; HYP_0137; HYP_0138; HYP_0139; HYP_0140; HYP_0141; HYP_0142; HYP_0143; HYP_0144; HYP_0145; HYP_0146; HYP_0147; HYP_0148; HYP_0149; HYP_0150; HYP_0151; HYP_0152; HYP_0153; HYP_0154; HYP_0155; HYP_0156; HYP_0157; HYP_0158; HYP_0159; HYP_0160; HYP_0161; HYP_0162; HYP_0163; HYP_0164; HYP_0165; HYP_0166; HYP_0167; HYP_0168; HYP_0169; HYP_0170; HYP_0171; HYP_0172; HYP_0173; HYP_0174; HYP_0175; HYP_0176; HYP_0177; HYP_0178; HYP_0179; HYPERMAQ; Hyperspectral and multi-mission high resolution optical remote sensing of aquatic environments; Identification; inherent optical properties; LATITUDE; LE_VERDON; LE_VERDON_GG13; LE_VERDON_GG14; LE_VERDON_GG15; LE_VERDON_GG16; LE_VERDON_GG17; LE_VERDON_GG18; LE_VERDON_GG19; LE_VERDON_GG20; LE_VERDON_GG21; LE_VERDON_GG22; LE_VERDON_GG23; LE_VERDON_GG24; LE_VERDON_GG39; LE_VERDON_GG40; LE_VERDON_GG41; LE_VERDON_GG42; LE_VERDON_GG43; LE_VERDON_GG44; LE_VERDON_GG45; LE_VERDON_GG46; LE_VERDON_GG47; LE_VERDON_GG48; LE_VERDON_GG49; LE_VERDON_GG50; LE_VERDON_GG51; LifeWatch_BE; LifeWatch BE; LONGITUDE; MULT; Multiple investigations; optically complex waters; PAUILLAC; PAUILLAC_GG01; PAUILLAC_GG02; PAUILLAC_GG03; PAUILLAC_GG04; PAUILLAC_GG05; PAUILLAC_GG06; PAUILLAC_GG07; PAUILLAC_GG08; PAUILLAC_GG09; PAUILLAC_GG10; PAUILLAC_GG11; PAUILLAC_GG12; PAUILLAC_GG25; PAUILLAC_GG26; PAUILLAC_GG27; PAUILLAC_GG28; PAUILLAC_GG29; PAUILLAC_GG30; PAUILLAC_GG31; PAUILLAC_GG32; PAUILLAC_GG33; PAUILLAC_GG34; PAUILLAC_GG35; PAUILLAC_GG36; PAUILLAC_GG37; PAUILLAC_GG38; radiometry; RIO_DE_LA_PLATA; RIO_DE_LA_PLATA_P01; RIO_DE_LA_PLATA_P02; RIO_DE_LA_PLATA_P03; RIO_DE_LA_PLATA_P04; RIO_DE_LA_PLATA_P05; RIO_DE_LA_PLATA_P06; RIO_DE_LA_PLATA_P07; RIO_DE_LA_PLATA_P08; RIO_DE_LA_PLATA_P09; RIO_DE_LA_PLATA_P10; RIO_DE_LA_PLATA_P11; RIO_DE_LA_PLATA_P12; RIO_DE_LA_PLATA_P13; RIO_DE_LA_PLATA_P14; RIO_DE_LA_PLATA_P15; RIO_DE_LA_PLATA_P16; RIO_DE_LA_PLATA_P17; RIO_DE_LA_PLATA_P18; RIO_DE_LA_PLATA_P19; RIO_DE_LA_PLATA_P20; RIO_DE_LA_PLATA_P21; RIO_DE_LA_PLATA_P22; Rubber boat; Sampling on land; Simon Stevin; SPUIKOM_APRIL2018; SPUIKOM_APRIL2018_SP38; SPUIKOM_APRIL2018_SP39a; SPUIKOM_APRIL2018_SP39b; SPUIKOM_APRIL2018_SP40a; SPUIKOM_APRIL2018_SP40b; SPUIKOM_APRIL2018_SP41; SPUIKOM_APRIL2018_SP42; SPUIKOM_APRIL2018_SP43; SPUIKOM_APRIL2018_SP44; SPUIKOM_JULY2018; SPUIKOM_JULY2018_SP50; SPUIKOM_JULY2018_SP51; SPUIKOM_JULY2018_SP52; SPUIKOM_JULY2018_SP53; SPUIKOM_JULY2018_SP54; SPUIKOM_JULY2018_SP55; SPUIKOM_JULY2018_SP56; SPUIKOM_JULY2018_SP57; SPUIKOM_JULY2018_SP58; SPUIKOM_JULY2018_SP59; SPUIKOM_JULY2018_SP60; SPUIKOM_JULY2018_SP62; SPUIKOM_JULY2018_SP63; SPUIKOM_JULY2018_SP64; SPUIKOM_JULY2018_SP65; SPUIKOM_JULY2018_SP66; SPUIKOM_JULY2018_SP67; SPUIKOM_JULY2018_SP68; Station label; Suspended particulate inorganic matter; Suspended particulate inorganic matter, standard deviation; Suspended particulate matter; Suspended particulate matter, standard deviation; turbidity; Turbidity, standard deviation; Turbidity (Formazin Backscatter Unit); Turbidity (Formazin nephelometric unit); Turbidity meter, HACH, portable; Turbidity meter, OBS501; water reflectance
    Type: Dataset
    Format: text/tab-separated-values, 1765 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 7
    facet.materialart.
    Unknown
    Water reflectance from six different study areas (in Argentina, China, France and Belgium) measured with TRiOS (2022)
    PANGAEA
    Details
    Publication Date: 2023-08-07
    Keywords: BELGIUM_WATERS_APRIL2018; BELGIUM_WATERS_APRIL2018_ST130; BELGIUM_WATERS_APRIL2018_ST215; BELGIUM_WATERS_APRIL2018_ST230; BELGIUM_WATERS_APRIL2018_ST330; BELGIUM_WATERS_APRIL2018_ST700; BELGIUM_WATERS_APRIL2018_ST710; BELGIUM_WATERS_APRIL2018_ST780; BELGIUM_WATERS_APRIL2018_W07BIS; BELGIUM_WATERS_JULY2018; BELGIUM_WATERS_JULY2018_LW_120; BELGIUM_WATERS_JULY2018_LW_130; BELGIUM_WATERS_JULY2018_LW_215; BELGIUM_WATERS_JULY2018_LW_230; BELGIUM_WATERS_JULY2018_LW_330; BELGIUM_WATERS_JULY2018_LW_700; BELGIUM_WATERS_JULY2018_LW_710; BELGIUM_WATERS_JULY2018_LW_780; BELGIUM_WATERS_JULY2018_LW_Harbour; BELGIUM_WATERS_JULY2018_LW_ZG02; Campaign; CHASCOMUS; CHASCOMUS_C01; CHASCOMUS_C02; CHASCOMUS_C03; CHASCOMUS_C04; CHASCOMUS_C05; chlorophyll-a concentration; DATE/TIME; DEPTH, water; Event label; HYP_0001; HYP_0002; HYP_0003; HYP_0004; HYP_0005; HYP_0006; HYP_0007; HYP_0008; HYP_0010; HYP_0011; HYP_0012; HYP_0013; HYP_0014; HYP_0015; HYP_0016; HYP_0017; HYP_0018; HYP_0019; HYP_0020; HYP_0021; HYP_0022; HYP_0023; HYP_0024; HYP_0081; HYP_0082; HYP_0083; HYP_0084; HYP_0085; HYP_0086; HYP_0087; HYP_0088; HYP_0089; HYP_0090; HYP_0091; HYP_0094; HYP_0095; HYP_0096; HYP_0097; HYP_0098; HYP_0099; HYP_0100; HYP_0101; HYP_0102; HYP_0103; HYP_0104; HYP_0105; HYP_0106; HYP_0107; HYP_0108; HYP_0109; HYP_0110; HYP_0111; HYP_0112; HYP_0113; HYP_0114; HYP_0115; HYP_0117; HYP_0118; HYP_0119; HYP_0120; HYP_0121; HYP_0122; HYP_0123; HYP_0124; HYP_0125; HYP_0126; HYP_0127; HYP_0128; HYP_0129; HYP_0130; HYP_0131; HYP_0132; HYP_0133; HYP_0134; HYP_0135; HYP_0136; HYP_0137; HYP_0138; HYP_0139; HYP_0140; HYP_0141; HYP_0142; HYP_0143; HYP_0144; HYP_0145; HYP_0146; HYP_0153; HYP_0155; HYP_0157; HYP_0158; HYP_0159; HYP_0160; HYP_0161; HYP_0162; HYP_0163; HYP_0164; HYP_0165; HYP_0166; HYP_0167; HYP_0168; HYP_0169; HYP_0170; HYP_0171; HYP_0172; HYP_0173; HYP_0174; HYP_0175; HYP_0176; HYP_0177; HYP_0178; HYP_0179; HYPERMAQ; Hyperspectral and multi-mission high resolution optical remote sensing of aquatic environments; Identification; inherent optical properties; LATITUDE; LE_VERDON; LE_VERDON_GG14; LE_VERDON_GG15; LE_VERDON_GG16; LE_VERDON_GG17; LE_VERDON_GG18; LE_VERDON_GG19; LE_VERDON_GG20; LE_VERDON_GG21; LE_VERDON_GG22; LE_VERDON_GG23; LE_VERDON_GG24; LE_VERDON_GG41; LE_VERDON_GG42; LE_VERDON_GG43; LE_VERDON_GG44; LE_VERDON_GG45; LE_VERDON_GG46; LE_VERDON_GG47; LE_VERDON_GG48; LE_VERDON_GG49; LE_VERDON_GG50; LE_VERDON_GG51; LifeWatch_BE; LifeWatch BE; LONGITUDE; MULT; Multiple investigations; optically complex waters; PAUILLAC; PAUILLAC_GG01; PAUILLAC_GG02; PAUILLAC_GG03; PAUILLAC_GG04; PAUILLAC_GG05; PAUILLAC_GG06; PAUILLAC_GG07; PAUILLAC_GG08; PAUILLAC_GG09; PAUILLAC_GG10; PAUILLAC_GG11; PAUILLAC_GG25; PAUILLAC_GG26; PAUILLAC_GG27; PAUILLAC_GG28; PAUILLAC_GG29; PAUILLAC_GG30; PAUILLAC_GG31; PAUILLAC_GG32; PAUILLAC_GG33; PAUILLAC_GG34; PAUILLAC_GG35; PAUILLAC_GG36; PAUILLAC_GG37; PAUILLAC_GG38; Radiometer, TriOS; radiometry; RIO_DE_LA_PLATA; RIO_DE_LA_PLATA_P01; RIO_DE_LA_PLATA_P02; RIO_DE_LA_PLATA_P03; RIO_DE_LA_PLATA_P04; RIO_DE_LA_PLATA_P05; RIO_DE_LA_PLATA_P06; RIO_DE_LA_PLATA_P07; RIO_DE_LA_PLATA_P08; RIO_DE_LA_PLATA_P09; RIO_DE_LA_PLATA_P10; RIO_DE_LA_PLATA_P11; RIO_DE_LA_PLATA_P12; RIO_DE_LA_PLATA_P13; RIO_DE_LA_PLATA_P14; RIO_DE_LA_PLATA_P15; RIO_DE_LA_PLATA_P16; Rubber boat; Sampling on land; Simon Stevin; SPUIKOM_APRIL2018; SPUIKOM_APRIL2018_SP38; SPUIKOM_APRIL2018_SP39b; SPUIKOM_APRIL2018_SP40b; SPUIKOM_APRIL2018_SP41; SPUIKOM_APRIL2018_SP42; SPUIKOM_APRIL2018_SP43; SPUIKOM_APRIL2018_SP44; SPUIKOM_JULY2018; SPUIKOM_JULY2018_SP50; SPUIKOM_JULY2018_SP51; SPUIKOM_JULY2018_SP52; SPUIKOM_JULY2018_SP53; SPUIKOM_JULY2018_SP54; SPUIKOM_JULY2018_SP55; SPUIKOM_JULY2018_SP56; SPUIKOM_JULY2018_SP57; SPUIKOM_JULY2018_SP58; SPUIKOM_JULY2018_SP59; SPUIKOM_JULY2018_SP60; SPUIKOM_JULY2018_SP62; SPUIKOM_JULY2018_SP63; SPUIKOM_JULY2018_SP64; SPUIKOM_JULY2018_SP65; SPUIKOM_JULY2018_SP66; SPUIKOM_JULY2018_SP67; SPUIKOM_JULY2018_SP68; Station label; Suspended particulate matter; turbidity; water reflectance; Water reflectance at 350 nm; Water reflectance at 352.5 nm; Water reflectance at 355 nm; Water reflectance at 357.5 nm; Water reflectance at 360 nm; Water reflectance at 362.5 nm; Water reflectance at 365 nm; Water reflectance at 367.5 nm; Water reflectance at 370 nm; Water reflectance at 372.5 nm; Water reflectance at 375 nm; Water reflectance at 377.5 nm; Water reflectance at 380 nm; Water reflectance at 382.5 nm; Water reflectance at 385 nm; Water reflectance at 387.5 nm; Water reflectance at 390 nm; Water reflectance at 392.5 nm; Water reflectance at 395 nm; Water reflectance at 397.5 nm; Water reflectance at 400 nm; Water reflectance at 402.5 nm; Water reflectance at 405 nm; Water reflectance at 407.5 nm; Water reflectance at 410 nm; Water reflectance at 412.5 nm; Water reflectance at 415 nm; Water reflectance at 417.5 nm; Water reflectance at 420 nm; Water reflectance at 422.5 nm; Water reflectance at 425 nm; Water reflectance at 427.5 nm; Water reflectance at 430 nm; Water reflectance at 432.5 nm; Water reflectance at 435 nm; Water reflectance at 437.5 nm; Water reflectance at 440 nm; Water reflectance at 442.5 nm; Water reflectance at 445 nm; Water reflectance at 447.5 nm; Water reflectance at 450 nm; Water reflectance at 452.5 nm; Water reflectance at 455 nm; Water reflectance at 457.5 nm; Water reflectance at 460 nm; Water reflectance at 462.5 nm; Water reflectance at 465 nm; Water reflectance at 467.5 nm; Water reflectance at 470 nm; Water reflectance at 472.5 nm; Water reflectance at 475 nm; Water reflectance at 477.5 nm; Water reflectance at 480 nm; Water reflectance at 482.5 nm; Water reflectance at 485 nm; Water reflectance at 487.5 nm; Water reflectance at 490 nm; Water reflectance at 492.5 nm; Water reflectance at 495 nm; Water reflectance at 497.5 nm; Water reflectance at 500 nm; Water reflectance at 502.5 nm; Water reflectance at 505 nm; Water reflectance at 507.5 nm; Water reflectance at 510 nm; Water reflectance at 512.5 nm; Water reflectance at 515 nm; Water reflectance at 517.5 nm; Water reflectance at 520 nm; Water reflectance at 522.5 nm; Water reflectance at 525 nm; Water reflectance at 527.5 nm; Water reflectance at 530 nm; Water reflectance at 532.5 nm; Water reflectance at 535 nm; Water reflectance at 537.5 nm; Water reflectance at 540 nm; Water reflectance at 542.5 nm; Water reflectance at 545 nm; Water reflectance at 547.5 nm; Water reflectance at 550 nm; Water reflectance at 552.5 nm; Water reflectance at 555 nm; Water reflectance at 557.5 nm; Water reflectance at 560 nm; Water reflectance at 562.5 nm; Water reflectance at 565 nm; Water reflectance at 567.5 nm; Water reflectance at 570 nm; Water reflectance at 572.5 nm; Water reflectance at 575 nm; Water reflectance at 577.5 nm; Water reflectance at 580 nm; Water reflectance at 582.5 nm; Water reflectance at 585 nm; Water reflectance at 587.5 nm; Water reflectance at 590 nm; Water reflectance at 592.5 nm; Water reflectance at 595 nm; Water reflectance at 597.5 nm; Water reflectance at 600 nm; Water reflectance at 602.5 nm; Water reflectance at 605 nm; Water reflectance at 607.5 nm; Water reflectance at 610 nm; Water reflectance at 612.5 nm; Water reflectance at 615 nm; Water reflectance at 617.5 nm; Water reflectance at 620 nm; Water reflectance at 622.5 nm; Water reflectance at 625 nm; Water reflectance at 627.5 nm; Water reflectance at 630 nm; Water reflectance at 632.5 nm; Water reflectance at 635 nm; Water reflectance at 637.5 nm; Water reflectance at 640 nm; Water reflectance at 642.5 nm; Water reflectance at 645 nm; Water reflectance at 647.5 nm; Water reflectance at 650 nm; Water reflectance at 652.5 nm; Water reflectance at 655 nm; Water reflectance at 657.5 nm; Water reflectance at 660 nm; Water reflectance at 662.5 nm; Water reflectance at 665 nm; Water reflectance at 667.5 nm; Water reflectance at 670 nm; Water reflectance at 672.5 nm; Water reflectance at 675 nm; Water reflectance at 677.5 nm;
    Type: Dataset
    Format: text/tab-separated-values, 24864 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 8
    facet.materialart.
    Unknown
    Downwelling sky radiance standard deviation from six different study areas (in Argentina, China, France and Belgium) measured with TRiOS (2022)
    PANGAEA
    Details
    Publication Date: 2023-08-07
    Keywords: BELGIUM_WATERS_APRIL2018; BELGIUM_WATERS_APRIL2018_ST130; BELGIUM_WATERS_APRIL2018_ST215; BELGIUM_WATERS_APRIL2018_ST230; BELGIUM_WATERS_APRIL2018_ST330; BELGIUM_WATERS_APRIL2018_ST700; BELGIUM_WATERS_APRIL2018_ST710; BELGIUM_WATERS_APRIL2018_ST780; BELGIUM_WATERS_APRIL2018_W07BIS; BELGIUM_WATERS_JULY2018; BELGIUM_WATERS_JULY2018_LW_120; BELGIUM_WATERS_JULY2018_LW_130; BELGIUM_WATERS_JULY2018_LW_215; BELGIUM_WATERS_JULY2018_LW_230; BELGIUM_WATERS_JULY2018_LW_330; BELGIUM_WATERS_JULY2018_LW_700; BELGIUM_WATERS_JULY2018_LW_710; BELGIUM_WATERS_JULY2018_LW_780; BELGIUM_WATERS_JULY2018_LW_Harbour; BELGIUM_WATERS_JULY2018_LW_ZG02; Campaign; CHASCOMUS; CHASCOMUS_C01; CHASCOMUS_C02; CHASCOMUS_C03; CHASCOMUS_C04; CHASCOMUS_C05; chlorophyll-a concentration; DATE/TIME; Event label; HYP_0001; HYP_0002; HYP_0003; HYP_0004; HYP_0005; HYP_0006; HYP_0007; HYP_0008; HYP_0010; HYP_0011; HYP_0012; HYP_0013; HYP_0014; HYP_0015; HYP_0016; HYP_0017; HYP_0018; HYP_0019; HYP_0020; HYP_0021; HYP_0022; HYP_0023; HYP_0024; HYP_0081; HYP_0082; HYP_0083; HYP_0084; HYP_0085; HYP_0086; HYP_0087; HYP_0088; HYP_0089; HYP_0090; HYP_0091; HYP_0094; HYP_0095; HYP_0096; HYP_0097; HYP_0098; HYP_0099; HYP_0100; HYP_0101; HYP_0102; HYP_0103; HYP_0104; HYP_0105; HYP_0106; HYP_0107; HYP_0108; HYP_0109; HYP_0110; HYP_0111; HYP_0112; HYP_0113; HYP_0114; HYP_0115; HYP_0117; HYP_0118; HYP_0119; HYP_0120; HYP_0121; HYP_0122; HYP_0123; HYP_0124; HYP_0125; HYP_0126; HYP_0127; HYP_0128; HYP_0129; HYP_0130; HYP_0131; HYP_0132; HYP_0133; HYP_0134; HYP_0135; HYP_0136; HYP_0137; HYP_0138; HYP_0139; HYP_0140; HYP_0141; HYP_0142; HYP_0143; HYP_0144; HYP_0145; HYP_0146; HYP_0153; HYP_0155; HYP_0157; HYP_0158; HYP_0159; HYP_0160; HYP_0161; HYP_0162; HYP_0163; HYP_0164; HYP_0165; HYP_0166; HYP_0167; HYP_0168; HYP_0169; HYP_0170; HYP_0171; HYP_0172; HYP_0173; HYP_0174; HYP_0175; HYP_0176; HYP_0177; HYP_0178; HYP_0179; HYPERMAQ; Hyperspectral and multi-mission high resolution optical remote sensing of aquatic environments; Identification; inherent optical properties; LATITUDE; LE_VERDON; LE_VERDON_GG14; LE_VERDON_GG15; LE_VERDON_GG16; LE_VERDON_GG17; LE_VERDON_GG18; LE_VERDON_GG19; LE_VERDON_GG20; LE_VERDON_GG21; LE_VERDON_GG22; LE_VERDON_GG23; LE_VERDON_GG24; LE_VERDON_GG41; LE_VERDON_GG42; LE_VERDON_GG43; LE_VERDON_GG44; LE_VERDON_GG45; LE_VERDON_GG46; LE_VERDON_GG47; LE_VERDON_GG48; LE_VERDON_GG49; LE_VERDON_GG50; LE_VERDON_GG51; LifeWatch_BE; LifeWatch BE; LONGITUDE; MULT; Multiple investigations; optically complex waters; PAUILLAC; PAUILLAC_GG01; PAUILLAC_GG02; PAUILLAC_GG03; PAUILLAC_GG04; PAUILLAC_GG05; PAUILLAC_GG06; PAUILLAC_GG07; PAUILLAC_GG08; PAUILLAC_GG09; PAUILLAC_GG10; PAUILLAC_GG11; PAUILLAC_GG25; PAUILLAC_GG26; PAUILLAC_GG27; PAUILLAC_GG28; PAUILLAC_GG29; PAUILLAC_GG30; PAUILLAC_GG31; PAUILLAC_GG32; PAUILLAC_GG33; PAUILLAC_GG34; PAUILLAC_GG35; PAUILLAC_GG36; PAUILLAC_GG37; PAUILLAC_GG38; Radiometer, TriOS; radiometry; RIO_DE_LA_PLATA; RIO_DE_LA_PLATA_P01; RIO_DE_LA_PLATA_P02; RIO_DE_LA_PLATA_P03; RIO_DE_LA_PLATA_P04; RIO_DE_LA_PLATA_P05; RIO_DE_LA_PLATA_P06; RIO_DE_LA_PLATA_P07; RIO_DE_LA_PLATA_P08; RIO_DE_LA_PLATA_P09; RIO_DE_LA_PLATA_P10; RIO_DE_LA_PLATA_P11; RIO_DE_LA_PLATA_P12; RIO_DE_LA_PLATA_P13; RIO_DE_LA_PLATA_P14; RIO_DE_LA_PLATA_P15; RIO_DE_LA_PLATA_P16; Rubber boat; Sampling on land; Simon Stevin; Spectral radiance, downward at 350 nm standard deviation; Spectral radiance, downward at 352.5 nm standard deviation; Spectral radiance, downward at 355 nm standard deviation; Spectral radiance, downward at 357.5 nm standard deviation; Spectral radiance, downward at 360 nm standard deviation; Spectral radiance, downward at 362.5 nm standard deviation; Spectral radiance, downward at 365 nm standard deviation; Spectral radiance, downward at 367.5 nm standard deviation; Spectral radiance, downward at 370 nm standard deviation; Spectral radiance, downward at 372.5 nm standard deviation; Spectral radiance, downward at 375 nm standard deviation; Spectral radiance, downward at 377.5 nm standard deviation; Spectral radiance, downward at 380 nm standard deviation; Spectral radiance, downward at 382.5 nm standard deviation; Spectral radiance, downward at 385 nm standard deviation; Spectral radiance, downward at 387.5 nm standard deviation; Spectral radiance, downward at 390 nm standard deviation; Spectral radiance, downward at 392.5 nm standard deviation; Spectral radiance, downward at 395 nm standard deviation; Spectral radiance, downward at 397.5 nm standard deviation; Spectral radiance, downward at 400 nm standard deviation; Spectral radiance, downward at 402.5 nm standard deviation; Spectral radiance, downward at 405 nm standard deviation; Spectral radiance, downward at 407.5 nm standard deviation; Spectral radiance, downward at 410 nm standard deviation; Spectral radiance, downward at 412.5 nm standard deviation; Spectral radiance, downward at 415 nm standard deviation; Spectral radiance, downward at 417.5 nm standard deviation; Spectral radiance, downward at 420 nm standard deviation; Spectral radiance, downward at 422.5 nm standard deviation; Spectral radiance, downward at 425 nm standard deviation; Spectral radiance, downward at 427.5 nm standard deviation; Spectral radiance, downward at 430 nm standard deviation; Spectral radiance, downward at 432.5 nm standard deviation; Spectral radiance, downward at 435 nm standard deviation; Spectral radiance, downward at 437.5 nm standard deviation; Spectral radiance, downward at 440 nm standard deviation; Spectral radiance, downward at 442.5 nm standard deviation; Spectral radiance, downward at 445 nm standard deviation; Spectral radiance, downward at 447.5 nm standard deviation; Spectral radiance, downward at 450 nm standard deviation; Spectral radiance, downward at 452.5 nm standard deviation; Spectral radiance, downward at 455 nm standard deviation; Spectral radiance, downward at 457.5 nm standard deviation; Spectral radiance, downward at 460 nm standard deviation; Spectral radiance, downward at 462.5 nm standard deviation; Spectral radiance, downward at 465 nm standard deviation; Spectral radiance, downward at 467.5 nm standard deviation; Spectral radiance, downward at 470 nm standard deviation; Spectral radiance, downward at 472.5 nm standard deviation; Spectral radiance, downward at 475 nm standard deviation; Spectral radiance, downward at 477.5 nm standard deviation; Spectral radiance, downward at 480 nm standard deviation; Spectral radiance, downward at 482.5 nm standard deviation; Spectral radiance, downward at 485 nm standard deviation; Spectral radiance, downward at 487.5 nm standard deviation; Spectral radiance, downward at 490 nm standard deviation; Spectral radiance, downward at 492.5 nm standard deviation; Spectral radiance, downward at 495 nm standard deviation; Spectral radiance, downward at 497.5 nm standard deviation; Spectral radiance, downward at 500 nm standard deviation; Spectral radiance, downward at 502.5 nm standard deviation; Spectral radiance, downward at 505 nm standard deviation; Spectral radiance, downward at 507.5 nm standard deviation; Spectral radiance, downward at 510 nm standard deviation; Spectral radiance, downward at 512.5 nm standard deviation; Spectral radiance, downward at 515 nm standard deviation; Spectral radiance, downward at 517.5 nm standard deviation; Spectral radiance, downward at 520 nm standard deviation; Spectral radiance, downward at 522.5 nm standard deviation; Spectral radiance, downward at 525 nm standard deviation; Spectral radiance, downward at 527.5 nm standard deviation; Spectral radiance, downward at 530 nm standard deviation; Spectral radiance, downward at 532.5 nm standard deviation; Spectral radiance, downward at 535 nm standard deviation; Spectral radiance, downward at 537.5 nm standard deviation; Spectral radiance, downward at 540 nm standard deviation; Spectral radiance, downward at 542.5 nm standard deviation; Spectral radiance, downward at 545 nm standard deviation; Spectral
    Type: Dataset
    Format: text/tab-separated-values, 24864 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 9
    facet.materialart.
    Unknown
    Pigment concentration in surface water from six different study areas (in Argentina, China, France and Belgium) measured with HPLC (2022)
    PANGAEA
    Details
    Publication Date: 2023-08-07
    Keywords: 19-Butanoyloxyfucoxanthin; 19-Hexanoyloxyfucoxanthin; Alloxanthin; alpha-Carotene; Antheraxanthin; BELGIUM_WATERS_APRIL2018; BELGIUM_WATERS_APRIL2018_ST130; BELGIUM_WATERS_APRIL2018_ST215; BELGIUM_WATERS_APRIL2018_ST230; BELGIUM_WATERS_APRIL2018_ST330; BELGIUM_WATERS_APRIL2018_ST700; BELGIUM_WATERS_APRIL2018_ST710; BELGIUM_WATERS_APRIL2018_ST780; BELGIUM_WATERS_APRIL2018_W07BIS; BELGIUM_WATERS_APRIL2018_ZG02; BELGIUM_WATERS_JULY2018; BELGIUM_WATERS_JULY2018_LW_120; BELGIUM_WATERS_JULY2018_LW_130; BELGIUM_WATERS_JULY2018_LW_215; BELGIUM_WATERS_JULY2018_LW_230; BELGIUM_WATERS_JULY2018_LW_330; BELGIUM_WATERS_JULY2018_LW_700; BELGIUM_WATERS_JULY2018_LW_710; BELGIUM_WATERS_JULY2018_LW_780; BELGIUM_WATERS_JULY2018_LW_ZG02; beta-Carotene; Campaign; Carotene; Chlorophyll a; chlorophyll-a concentration; Chlorophyll b; Chlorophyll c1+c2; Chlorophyll c3; Chlorophyllide a; DATE/TIME; DEPTH, water; Diadinoxanthin; Diatoxanthin; Event label; Fucoxanthin; High Performance Liquid Chromatography (HPLC); HYP_0001; HYP_0002; HYP_0003; HYP_0004; HYP_0005; HYP_0006; HYP_0007; HYP_0008; HYP_0009; HYP_0010; HYP_0011; HYP_0012; HYP_0013; HYP_0014; HYP_0015; HYP_0016; HYP_0017; HYP_0019; HYP_0080; HYP_0082; HYP_0085; HYP_0087; HYP_0089; HYP_0091; HYP_0094; HYP_0096; HYP_0098; HYP_0100; HYP_0102; HYP_0104; HYP_0105; HYP_0107; HYP_0109; HYP_0111; HYP_0113; HYP_0115; HYP_0118; HYP_0120; HYP_0122; HYP_0124; HYP_0126; HYP_0128; HYP_0130; HYP_0154; HYP_0156; HYP_0158; HYP_0159; HYP_0160; HYP_0161; HYP_0162; HYP_0163; HYP_0164; HYP_0165; HYP_0166; HYP_0167; HYP_0168; HYP_0169; HYP_0170; HYP_0171; HYP_0172; HYPERMAQ; Hyperspectral and multi-mission high resolution optical remote sensing of aquatic environments; inherent optical properties; LATITUDE; LE_VERDON; LE_VERDON_GG13; LE_VERDON_GG15; LE_VERDON_GG18; LE_VERDON_GG20; LE_VERDON_GG22; LE_VERDON_GG24; LE_VERDON_GG41; LE_VERDON_GG43; LE_VERDON_GG45; LE_VERDON_GG47; LE_VERDON_GG49; LE_VERDON_GG51; LifeWatch_BE; LifeWatch BE; LONGITUDE; Lutein; MULT; Multiple investigations; Neoxanthin; optically complex waters; PAUILLAC; PAUILLAC_GG01; PAUILLAC_GG03; PAUILLAC_GG05; PAUILLAC_GG07; PAUILLAC_GG09; PAUILLAC_GG11; PAUILLAC_GG26; PAUILLAC_GG28; PAUILLAC_GG30; PAUILLAC_GG32; PAUILLAC_GG34; PAUILLAC_GG36; PAUILLAC_GG38; Peridinin; Phaeophorbide a; Phaeophytin a; Prasinoxanthin; radiometry; Rubber boat; Sample ID; Sampling on land; Simon Stevin; SPUIKOM_APRIL2018; SPUIKOM_APRIL2018_SP39a; SPUIKOM_APRIL2018_SP40a; SPUIKOM_APRIL2018_SP41; SPUIKOM_APRIL2018_SP42; SPUIKOM_APRIL2018_SP43; SPUIKOM_APRIL2018_SP44; SPUIKOM_JULY2018; SPUIKOM_JULY2018_SP50; SPUIKOM_JULY2018_SP51; SPUIKOM_JULY2018_SP52; SPUIKOM_JULY2018_SP53; SPUIKOM_JULY2018_SP54; SPUIKOM_JULY2018_SP55; SPUIKOM_JULY2018_SP56; SPUIKOM_JULY2018_SP57; SPUIKOM_JULY2018_SP58; SPUIKOM_JULY2018_SP59; SPUIKOM_JULY2018_SP60; Station label; Suspended particulate matter; turbidity; Violaxanthin; water reflectance; Zeaxanthin
    Type: Dataset
    Format: text/tab-separated-values, 1510 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
  • 10
    facet.materialart.
    Unknown
    Spectral downwelling irradiance standard deviation from six different study areas (in Argentina, China, France and Belgium) measured with TRiOS (2022)
    PANGAEA
    Details
    Publication Date: 2023-08-07
    Keywords: BELGIUM_WATERS_APRIL2018; BELGIUM_WATERS_APRIL2018_ST130; BELGIUM_WATERS_APRIL2018_ST215; BELGIUM_WATERS_APRIL2018_ST230; BELGIUM_WATERS_APRIL2018_ST330; BELGIUM_WATERS_APRIL2018_ST700; BELGIUM_WATERS_APRIL2018_ST710; BELGIUM_WATERS_APRIL2018_ST780; BELGIUM_WATERS_APRIL2018_W07BIS; BELGIUM_WATERS_JULY2018; BELGIUM_WATERS_JULY2018_LW_120; BELGIUM_WATERS_JULY2018_LW_130; BELGIUM_WATERS_JULY2018_LW_215; BELGIUM_WATERS_JULY2018_LW_230; BELGIUM_WATERS_JULY2018_LW_330; BELGIUM_WATERS_JULY2018_LW_700; BELGIUM_WATERS_JULY2018_LW_710; BELGIUM_WATERS_JULY2018_LW_780; BELGIUM_WATERS_JULY2018_LW_Harbour; BELGIUM_WATERS_JULY2018_LW_ZG02; Campaign; CHASCOMUS; CHASCOMUS_C01; CHASCOMUS_C02; CHASCOMUS_C03; CHASCOMUS_C04; CHASCOMUS_C05; chlorophyll-a concentration; DATE/TIME; Event label; HYP_0001; HYP_0002; HYP_0003; HYP_0004; HYP_0005; HYP_0006; HYP_0007; HYP_0008; HYP_0010; HYP_0011; HYP_0012; HYP_0013; HYP_0014; HYP_0015; HYP_0016; HYP_0017; HYP_0018; HYP_0019; HYP_0020; HYP_0021; HYP_0022; HYP_0023; HYP_0024; HYP_0081; HYP_0082; HYP_0083; HYP_0084; HYP_0085; HYP_0086; HYP_0087; HYP_0088; HYP_0089; HYP_0090; HYP_0091; HYP_0094; HYP_0095; HYP_0096; HYP_0097; HYP_0098; HYP_0099; HYP_0100; HYP_0101; HYP_0102; HYP_0103; HYP_0104; HYP_0105; HYP_0106; HYP_0107; HYP_0108; HYP_0109; HYP_0110; HYP_0111; HYP_0112; HYP_0113; HYP_0114; HYP_0115; HYP_0117; HYP_0118; HYP_0119; HYP_0120; HYP_0121; HYP_0122; HYP_0123; HYP_0124; HYP_0125; HYP_0126; HYP_0127; HYP_0128; HYP_0129; HYP_0130; HYP_0131; HYP_0132; HYP_0133; HYP_0134; HYP_0135; HYP_0136; HYP_0137; HYP_0138; HYP_0139; HYP_0140; HYP_0141; HYP_0142; HYP_0143; HYP_0144; HYP_0145; HYP_0146; HYP_0153; HYP_0155; HYP_0157; HYP_0158; HYP_0159; HYP_0160; HYP_0161; HYP_0162; HYP_0163; HYP_0164; HYP_0165; HYP_0166; HYP_0167; HYP_0168; HYP_0169; HYP_0170; HYP_0171; HYP_0172; HYP_0173; HYP_0174; HYP_0175; HYP_0176; HYP_0177; HYP_0178; HYP_0179; HYPERMAQ; Hyperspectral and multi-mission high resolution optical remote sensing of aquatic environments; Identification; inherent optical properties; LATITUDE; LE_VERDON; LE_VERDON_GG14; LE_VERDON_GG15; LE_VERDON_GG16; LE_VERDON_GG17; LE_VERDON_GG18; LE_VERDON_GG19; LE_VERDON_GG20; LE_VERDON_GG21; LE_VERDON_GG22; LE_VERDON_GG23; LE_VERDON_GG24; LE_VERDON_GG41; LE_VERDON_GG42; LE_VERDON_GG43; LE_VERDON_GG44; LE_VERDON_GG45; LE_VERDON_GG46; LE_VERDON_GG47; LE_VERDON_GG48; LE_VERDON_GG49; LE_VERDON_GG50; LE_VERDON_GG51; LifeWatch_BE; LifeWatch BE; LONGITUDE; MULT; Multiple investigations; optically complex waters; PAUILLAC; PAUILLAC_GG01; PAUILLAC_GG02; PAUILLAC_GG03; PAUILLAC_GG04; PAUILLAC_GG05; PAUILLAC_GG06; PAUILLAC_GG07; PAUILLAC_GG08; PAUILLAC_GG09; PAUILLAC_GG10; PAUILLAC_GG11; PAUILLAC_GG25; PAUILLAC_GG26; PAUILLAC_GG27; PAUILLAC_GG28; PAUILLAC_GG29; PAUILLAC_GG30; PAUILLAC_GG31; PAUILLAC_GG32; PAUILLAC_GG33; PAUILLAC_GG34; PAUILLAC_GG35; PAUILLAC_GG36; PAUILLAC_GG37; PAUILLAC_GG38; Radiometer, TriOS; radiometry; RIO_DE_LA_PLATA; RIO_DE_LA_PLATA_P01; RIO_DE_LA_PLATA_P02; RIO_DE_LA_PLATA_P03; RIO_DE_LA_PLATA_P04; RIO_DE_LA_PLATA_P05; RIO_DE_LA_PLATA_P06; RIO_DE_LA_PLATA_P07; RIO_DE_LA_PLATA_P08; RIO_DE_LA_PLATA_P09; RIO_DE_LA_PLATA_P10; RIO_DE_LA_PLATA_P11; RIO_DE_LA_PLATA_P12; RIO_DE_LA_PLATA_P13; RIO_DE_LA_PLATA_P14; RIO_DE_LA_PLATA_P15; RIO_DE_LA_PLATA_P16; Rubber boat; Sampling on land; Simon Stevin; Spectral irradiance, downward at 350 nm, standard deviation; Spectral irradiance, downward at 352.5 nm, standard deviation; Spectral irradiance, downward at 355 nm, standard deviation; Spectral irradiance, downward at 357.5 nm, standard deviation; Spectral irradiance, downward at 360 nm, standard deviation; Spectral irradiance, downward at 362.5 nm, standard deviation; Spectral irradiance, downward at 365 nm, standard deviation; Spectral irradiance, downward at 367.5 nm, standard deviation; Spectral irradiance, downward at 370 nm, standard deviation; Spectral irradiance, downward at 372.5 nm, standard deviation; Spectral irradiance, downward at 375 nm, standard deviation; Spectral irradiance, downward at 377.5 nm, standard deviation; Spectral irradiance, downward at 380 nm, standard deviation; Spectral irradiance, downward at 382.5 nm, standard deviation; Spectral irradiance, downward at 385 nm, standard deviation; Spectral irradiance, downward at 387.5 nm, standard deviation; Spectral irradiance, downward at 390 nm, standard deviation; Spectral irradiance, downward at 392.5 nm, standard deviation; Spectral irradiance, downward at 395 nm, standard deviation; Spectral irradiance, downward at 397.5 nm, standard deviation; Spectral irradiance, downward at 400 nm, standard deviation; Spectral irradiance, downward at 402.5 nm, standard deviation; Spectral irradiance, downward at 405 nm, standard deviation; Spectral irradiance, downward at 407.5 nm, standard deviation; Spectral irradiance, downward at 410 nm, standard deviation; Spectral irradiance, downward at 412.5 nm, standard deviation; Spectral irradiance, downward at 415 nm, standard deviation; Spectral irradiance, downward at 417.5 nm, standard deviation; Spectral irradiance, downward at 420 nm, standard deviation; Spectral irradiance, downward at 422.5 nm, standard deviation; Spectral irradiance, downward at 425 nm, standard deviation; Spectral irradiance, downward at 427.5 nm, standard deviation; Spectral irradiance, downward at 430 nm, standard deviation; Spectral irradiance, downward at 432.5 nm, standard deviation; Spectral irradiance, downward at 435 nm, standard deviation; Spectral irradiance, downward at 437.5 nm, standard deviation; Spectral irradiance, downward at 440 nm, standard deviation; Spectral irradiance, downward at 442.5 nm, standard deviation; Spectral irradiance, downward at 445 nm, standard deviation; Spectral irradiance, downward at 447.5 nm, standard deviation; Spectral irradiance, downward at 450 nm, standard deviation; Spectral irradiance, downward at 452.5 nm, standard deviation; Spectral irradiance, downward at 455 nm, standard deviation; Spectral irradiance, downward at 457.5 nm, standard deviation; Spectral irradiance, downward at 460 nm, standard deviation; Spectral irradiance, downward at 462.5 nm, standard deviation; Spectral irradiance, downward at 465 nm, standard deviation; Spectral irradiance, downward at 467.5 nm, standard deviation; Spectral irradiance, downward at 470 nm, standard deviation; Spectral irradiance, downward at 472.5 nm, standard deviation; Spectral irradiance, downward at 475 nm, standard deviation; Spectral irradiance, downward at 477.5 nm, standard deviation; Spectral irradiance, downward at 480 nm, standard deviation; Spectral irradiance, downward at 482.5 nm, standard deviation; Spectral irradiance, downward at 485 nm, standard deviation; Spectral irradiance, downward at 487.5 nm, standard deviation; Spectral irradiance, downward at 490 nm, standard deviation; Spectral irradiance, downward at 492.5 nm, standard deviation; Spectral irradiance, downward at 495 nm, standard deviation; Spectral irradiance, downward at 497.5 nm, standard deviation; Spectral irradiance, downward at 500 nm, standard deviation; Spectral irradiance, downward at 502.5 nm, standard deviation; Spectral irradiance, downward at 505 nm, standard deviation; Spectral irradiance, downward at 507.5 nm, standard deviation; Spectral irradiance, downward at 510 nm, standard deviation; Spectral irradiance, downward at 512.5 nm, standard deviation; Spectral irradiance, downward at 515 nm, standard deviation; Spectral irradiance, downward at 517.5 nm, standard deviation; Spectral irradiance, downward at 520 nm, standard deviation; Spectral irradiance, downward at 522.5 nm, standard deviation; Spectral irradiance, downward at 525 nm, standard deviation; Spectral irradiance, downward at 527.5 nm, standard deviation; Spectral irradiance, downward at 530 nm, standard deviation; Spectral irradiance, downward at 532.5 nm, standard deviation; Spectral irradiance, downward at 535 nm, standard deviation; Spectral irradiance,
    Type: Dataset
    Format: text/tab-separated-values, 24975 data points
    Location Call Number Expected Availability
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    DATA PANGAEA
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