Citation:

PANGAEA.925701

Name: Particulate organic carbon composition, granulometric and geochemical data for suspended sediment from the Rio Bermejo (Argentina) collected in March 2017
Published: 2020-12-11
License: https://creativecommons.org/licenses/by/4.0/
Keywords: Grain Size; oxyhydroxide; Particulate organic carbon; radiocarbon; river sediment; surface area; TOC

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Abstract:

To study the transformation of organic carbon through long distance transport in rivers, we measured the composition of bulk organic carbon in river suspended sediment of the Rio Bermejo (northern Argentina). This river has a ~1300 km lowland flowpath with no significant tributaries. We collected fluvial suspended sediment in vertical depth profiles at five sampling locations along the length of the Rio Bermejo (northern Argentina) during near-bankfull conditions, when discharge varied between 675 and 1080 m3/s and banks were actively eroding. Additionally, we collected one depth profile from the Rio San Francisco (RSF) and one from the Rio Bermejo 10 km upstream of the RSF confluence. Combining these profiles and weighting them by the relative proportions of their total sediment load input to the mainstem Bermejo serves as a depth profile representing the headwaters. At each depth profile location, we collected water and suspended sediment from the channel thalweg by boat. We used a weighted 8-liter horizontal sampling bottle (Wildco Beta Plus bottle) with an attached pressure transducer to measure sampling depth. We separated sediment from the water using a custom-built 5-liter pressurized filtration unit with a 293 mm diameter, 0.2 µm polyethersulfone filter. In the laboratory, we rinsed sediment off the filters directly into an evaporating dish with ultrapure 18.2 MΩ water (pH~7). Samples were dried in an oven at 40ºC, and subsequently homogenized. Sediment particle size distributions were measured on ~10 mg aliquots using a laser diffraction particle size analyzer (Horiba LA-950). Specific surface area (SSA) of bulk sediment samples was measured on ~4 g aliquots using a Quantachrome NOVAtouch LX gas sorption analyzer and the Brunauer, Emmett, and Teller (BET) theory (Brunauer et al., 1938). Aliquots for organic carbon measurements were first treated with 4% HCl solution to remove inorganic carbon, following Galy et al. (2007, doi:10.1111/j.1751-908X.2007.00864.x). Total organic carbon (TOCPOC) and δ13C of POC was measured in duplicate at Durham University using a Costech elemental analyzer (EA) coupled to a CONFLO III and Thermo Scientific Delta V Advantage isotope ratio mass spectrometer (IRMS). Radiocarbon content was measured using an EA coupled to an accelerator mass spectrometer (EA-AMS) at ETH Zurich. We report 14C content as fraction modern (F14C), by normalizing measurements to 95% of the 1950 NBS Oxalic Acid II standard (δ13C = -17.8‰) and correcting for mass-dependent fractionation using a common δ13C value of -25‰. OC loading is the mass of organic carbon in a sample normalized by the sample's specific surface area (SSA). Reactive metals in the amorphous oxyhydroxide and crystalline oxide grain coatings, were extracted from the sediment samples using a procedure adapted from Wittmann et al. (2012, doi:10.1016/j.chemgeo.2012.04.031). The extracted oxyhydroxides and oxides were dried down and diluted in 3M HNO3. A 100 μl aliquot was taken for measurement of metal concentrations. Al, Fe, Mg, and Mn concentrations were measured using inductively coupled plasma optical emission spectroscopy (ICP-OES). Uncertainty of ICP-OES measurements was <5%. All depth-integrated values are calculated as a function of the suspended sediment concentration relative to the depth-averaged suspended sediment concentration.

Keyword(s):

Grain Size; oxyhydroxide; Particulate organic carbon; radiocarbon; river sediment; surface area; TOC

Related to:

Repasch, Marisa N; Scheingross, Joel S; Hovius, Niels; Lupker, Maarten; Wittmann, Hella; Haghipour, Negar; Gröcke, Darren R; Orfeo, Oscar; Eglinton, Timothy Ian; Sachse, Dirk (2021): Fluvial organic carbon cycling regulated by sediment transit time and mineral protection. Nature Geoscience, 14(11), 842-848, https://doi.org/10.1038/s41561-021-00845-7

Coverage:

Median Latitude: -24.473133 * Median Longitude: -62.009605 * South-bound Latitude: -26.660870 * West-bound Longitude: -64.198860 * North-bound Latitude: -23.144220 * East-bound Longitude: -58.634670

Date/Time Start: 2017-03-12T00:00:00 * Date/Time End: 2017-03-25T00:00:00

Minimum ELEVATION: 66 m a.s.l. * Maximum ELEVATION: 292 m a.s.l.

Event(s):

AR17MR-05 * Latitude: -26.660870 * Longitude: -58.634670 * Date/Time: 2017-03-12T00:00:00 * Elevation: 66.0 m * Location: General Mansilla * Comment: River km 1220

AR17MR-06 * Latitude: -26.660870 * Longitude: -58.634670 * Date/Time: 2017-03-12T00:00:00 * Elevation: 66.0 m * Location: General Mansilla * Comment: River km 1220

AR17MR-07 * Latitude: -26.660870 * Longitude: -58.634670 * Date/Time: 2017-03-12T00:00:00 * Elevation: 66.0 m * Location: General Mansilla * Comment: River km 1220

Parameter(s):

#	Name	Short Name	Unit	Principal Investigator	Method/Device	Comment
1	Event label	Event		Repasch, Marisa N
2	Sample ID	Sample ID		Repasch, Marisa N
3	DATE/TIME	Date/Time		Repasch, Marisa N		Geocode
4	LATITUDE	Latitude		Repasch, Marisa N		Geocode
5	LONGITUDE	Longitude		Repasch, Marisa N		Geocode
6	ELEVATION	Elevation	m a.s.l.	Repasch, Marisa N		Geocode
7	Distance	Distance	km	Repasch, Marisa N		Along channel, measured downstream from the Rio Bermejo-Rio San Francisco confluence; 0: Rio San Francisco, -: indicates tributary upstream of the mainstem Rio Bermejo
8	Sediment transit time	Sed transit	a	Repasch, Marisa N
9	Sediment transit time, uncertainty	Sed transit unc	±	Repasch, Marisa N
10	Depth, relative	Depth rel	%	Repasch, Marisa N		Relative water depth: 0 is the river water surface, and 100 is the river bed
11	Depth comment	Depth comm		Repasch, Marisa N
12	Median, grain size	D50	µm	Repasch, Marisa N	Scattering Particle Size Distribution Analyzer LA-950 (Horiba)
13	Size fraction < 0.030 mm	<30 µm	%	Repasch, Marisa N	Scattering Particle Size Distribution Analyzer LA-950 (Horiba)
14	Suspended sediment concentration	SSC	g/l	Repasch, Marisa N
15	Suspended sediment concentration	SSC	g/l	Repasch, Marisa N	Weighted average	Depth-integrated values; weighted averages, weighted by the suspended sediment concentrations at sampling point
16	Carbon, organic, total	TOC	%	Repasch, Marisa N	Element analyser CHN (Costech) coupled to a CONFLO III and Thermo Scientific Delta V Advantage isotope ratio mass spectrometer (IRMS)
17	Carbon, organic, total	TOC	%	Repasch, Marisa N	Weighted average	Depth-integrated values; weighted averages, weighted by the suspended sediment concentrations at sampling point
18	Carbon, organic, total, standard error	TOC std e	±	Repasch, Marisa N
19	Specific surface area	SSA	m²/g	Repasch, Marisa N	Gas sorption analyszer (Quantachrome NOVAtouch LX) and BET-method (Brunauer et al., 1938)	Mineral specific surface area
20	Specific surface area	SSA	m²/g	Repasch, Marisa N	Weighted average	Mineral specific surface area; depth-integrated values; weighted averages, weighted by the suspended sediment concentrations at sampling point
21	Carbon, organic, loading	C org loading	mg/m²	Repasch, Marisa N	Normalized	Mass of organic carbon per unit mineral surface area
22	Carbon, organic, loading	C org loading	mg/m²	Repasch, Marisa N	Weighted average	Mass of organic carbon per unit mineral surface area, depth-integrated values; weighted averages, weighted by the suspended sediment concentrations at sampling point
23	Carbon, organic, loading, standard error	C org loading std e	±	Repasch, Marisa N
24	δ13C	δ13C	‰ PDB	Repasch, Marisa N	Element analyser CHN (Costech) coupled to a CONFLO III and Thermo Scientific Delta V Advantage isotope ratio mass spectrometer (IRMS)
25	δ13C	δ13C	‰ PDB	Repasch, Marisa N	Weighted average	Depth-integrated values; weighted averages, weighted by the suspended sediment concentrations at sampling point
26	δ13C, standard error	δ13C std e	±	Repasch, Marisa N
27	Fraction modern carbon	F14C		Repasch, Marisa N	Element analyzer coupled to an accelerator mass spectrometer (EA-AMS)
28	Fraction modern carbon	F14C		Repasch, Marisa N	Weighted average	Depth-integrated values; weighted averages, weighted by the suspended sediment concentrations at sampling point
29	Fraction modern carbon, standard error	F14C std e	±	Repasch, Marisa N
30	Fraction modern carbon	F14C		Repasch, Marisa N	Element analyzer coupled to an accelerator mass spectrometer (EA-AMS)	Long-chain leaf wax n-alkanes (C27, C29, C31, and C33)
31	Fraction modern carbon, standard error	F14C std e	±	Repasch, Marisa N		Long-chain leaf wax n-alkanes (C27, C29, C31, and C33)
32	Aluminium, reactive	Al react	%	Repasch, Marisa N	ICP-OES, Inductively coupled plasma - optical emission spectrometry	Measured in the acid-extractable reactive mineral phase
33	Iron, reactive	Fe react	%	Repasch, Marisa N	ICP-OES, Inductively coupled plasma - optical emission spectrometry	Measured in the acid-extractable reactive mineral phase
34	Manganese, reactive	Mn react	%	Repasch, Marisa N	ICP-OES, Inductively coupled plasma - optical emission spectrometry	Measured in the acid-extractable reactive mineral phase
35	Magnesium, reactive	Mg react	%	Repasch, Marisa N	ICP-OES, Inductively coupled plasma - optical emission spectrometry	Measured in the acid-extractable reactive mineral phase
36	Reactive minerals, total	React min tot	%	Repasch, Marisa N	ICP-OES, Inductively coupled plasma - optical emission spectrometry	Measured in the acid-extractable reactive mineral phase

License:

Creative Commons Attribution 4.0 International (CC-BY-4.0)

Size:

528 data points

Data

Download dataset as tab-delimited text — use the following character encoding:

1 Event	2 Sample ID	3 Date/Time	4 Latitude	5 Longitude	6 Elevation [m a.s.l.]	7 Distance [km] (Along channel, measured downs...)	8 Sed transit [a]	9 Sed transit unc [±]	10 Depth rel [%] (Relative water depth: 0 is th...)	11 Depth comm	12 D50 [µm] (Scattering Particle Size Dist...)	13 <30 µm [%] (Scattering Particle Size Dist...)	14 SSC [g/l]	15 SSC [g/l] (Depth-integrated values; weig...)	16 TOC [%] (Element analyser CHN (Costech...)	17 TOC [%] (Depth-integrated values; weig...)	18 TOC std e [±]	19 SSA [m²/g] (Mineral specific surface area...)	20 SSA [m²/g] (Mineral specific surface area...)	21 C org loading [mg/m²] (Mass of organic carbon per un...)	22 C org loading [mg/m²] (Mass of organic carbon per un...)	23 C org loading std e [±]	24 δ13C [‰ PDB] (Element analyser CHN (Costech...)	25 δ13C [‰ PDB] (Depth-integrated values; weig...)	26 δ13C std e [±]	27 F14C (Element analyzer coupled to a...)	28 F14C (Depth-integrated values; weig...)	29 F14C std e [±]	30 F14C (Long-chain leaf wax n-alkanes...)	31 F14C std e [±] (Long-chain leaf wax n-alkanes...)	32 Al react [%] (Measured in the acid-extracta...)	33 Fe react [%] (Measured in the acid-extracta...)	34 Mn react [%] (Measured in the acid-extracta...)	35 Mg react [%] (Measured in the acid-extracta...)	36 React min tot [%] (Measured in the acid-extracta...)
AR17MR-31	AR17MR-31	2017-03-20	-23.35554	-64.18391	290	-15			0		15.2	20	4.000		0.31			12.60		0.24			-25.70		0.20	0.91		0.01			0.25	0.39	0.12	0.02	0.78
AR17MR-30	AR17MR-30	2017-03-20	-23.35554	-64.18391	290	-15			100		209.7	94			0.07			2.59		0.28			-27.27		0.20	0.92		0.01			0.07	0.10	0.03	0.00	0.21
AR17MR-30	AR17MR-31,AR17MR-30	2017-03-20	-23.35554	-64.18391	290	-15				Depth-integrated						0.19	0.12		7.59		0.26	0.02		-26.49	0.43		0.92	0.01
AR17MR-24	AR17MR-24	2017-03-19	-23.14422	-64.19886	292	-10			0		7.6	9	3.979		0.23			10.83		0.22			-26.29		0.20	0.80		0.01			0.30	0.64	0.22	0.03	1.19
AR17MR-25	AR17MR-25	2017-03-19	-23.25094	-64.13403	292	-10			30		140.7	62	6.942		0.18			7.76		0.23			-26.72		0.20	0.86		0.01			0.21	0.41	0.09	0.02	0.74
AR17MR-26	AR17MR-26	2017-03-19	-23.25094	-64.13403	292	-10			59		112.9	58	6.625					7.28		0.20			-24.90		0.20	0.78		0.01			0.22	0.38	0.09	0.02	0.72
AR17MR-27	AR17MR-27	2017-03-19	-23.25094	-64.13403	292	-10			100		324.2	100			0.01			1.16		0.07			-26.29		0.20	0.49		0.01			0.12	0.19	0.04	0.00	0.36
AR17MR-27	AR17MR-24,AR17MR-25,AR17MR-26,AR17MR-27	2017-03-19	-23.25094	-64.13403	292	-10				Depth-integrated				7.049		0.18	0.04		6.92		0.21	0.01		-26.04	0.30		0.82	0.01
CONFLUENCE	CONFLUENCE		-23.25094	-64.13403	292	0	0			Depth-integrated		67		7.000		0.18	0.06		5.88		0.22	0.03		-26.10	0.28		0.83	0.02
AR17MR-35	AR17MR-35	2017-03-21	-23.75598	-63.07393	225	135			0		8.2	9	3.714		0.30			14.00		0.21			-26.02		0.20	0.88		0.01	0.79	0.01	0.30	0.53	0.13	0.02	0.99
AR17MR-34	AR17MR-34	2017-03-21	-23.75598	-63.07393	225	135			25		21.0	38	6.282		0.22			10.67		0.21			-25.78		0.20	0.88		0.01			0.22	0.39	0.09	0.02	0.71
AR17MR-33	AR17MR-33	2017-03-21	-23.75598	-63.07393	225	135			50		15.0	27	7.120		0.20			8.96		0.22			-26.30		0.20	0.88		0.01	0.80	0.01	0.19	0.34	0.08	0.01	0.63
AR17MR-32	AR17MR-32	2017-03-21	-23.75598	-63.07393	225	135			75		9.6	15	4.590		0.28			11.48		0.24			-25.98		0.20	0.89		0.01			0.26	0.46	0.11	0.02	0.85
AR17MR-36	AR17MR-36	2017-03-21	-23.75598	-63.07393	225	135			100		132.4	95			0.06			3.18		0.18			-27.12		0.20	0.78		0.01			0.07	0.13	0.03	0.00	0.24
AR17MR-36	AR17MR-35,AR17MR-34,AR17MR-33,AR17MR-32,AR17MR-36	2017-03-21	-23.75598	-63.07393	225	135	350	270		Depth-integrated				5.320		0.24	0.04		11.32		0.22	0.01		-25.96	0.26		0.88	0.01
AR17MR-11	AR17MR-11	2017-03-15	-24.31326	-61.83789	172	420			0		6.3	4	6.826		0.36			23.15		0.16			-25.49		0.20	0.87		0.01	0.81	0.01	0.20	0.35	0.09	0.02	0.66
AR17MR-12	AR17MR-12	2017-03-15	-24.31326	-61.83789	172	420			20		14.2	23	12.348		0.32			12.25		0.26			-26.58		0.20	0.94		0.01			0.14	0.24	0.06	0.02	0.45
AR17MR-13	AR17MR-13	2017-03-15	-24.31326	-61.83789	172	420			30		35.5	39	23.913		0.27			11.37		0.23			-26.53		0.20	0.91		0.01	0.86	0.01	0.12	0.21	0.05	0.01	0.41
AR17MR-14	AR17MR-14	2017-03-15	-24.31326	-61.83789	172	420			49		15.7	25	17.000		0.30			12.77		0.24			-26.51		0.20	0.92		0.01			0.15	0.24	0.06	0.02	0.46
AR17MR-14	AR17MR-11,AR17MR-12,AR17MR-13,AR17MR-14	2017-03-15	-24.31326	-61.83789	172	420	840	324		Depth-integrated				18.672		0.30	0.04		11.95		0.23	0.04		-26.39	0.28		0.92	0.01
AR17MR-45	AR17MR-45	2017-03-25	-25.66380	-60.11595	101	865			0		7.4	4	5.908		0.27			22.49		0.12			-25.43		0.20	0.85		0.01	0.74	0.01	0.34	0.54	0.14	0.03	1.06
AR17MR-44	AR17MR-44	2017-03-25	-25.66380	-60.11595	101	865			35		10.1	8	7.858		0.24			19.66		0.12			-25.26		0.20	0.85		0.01			0.23	0.49	0.13	0.02	0.87
AR17MR-43	AR17MR-43	2017-03-25	-25.66380	-60.11595	101	865			62		11.9	16	9.238		0.23			16.08		0.14			-25.68		0.20	0.87		0.01	0.86	0.01	0.25	0.42	0.11	0.02	0.80
AR17MR-42	AR17MR-42	2017-03-25	-25.66380	-60.11595	101	865			80		38.4	38	15.435		0.20			12.25		0.16			-26.08		0.20	0.92		0.01			0.20	0.22	0.06	0.01	0.50
AR17MR-46	AR17MR-46	2017-03-25	-25.66380	-60.11595	101	865			100		160.3	97				0.01		2.16		0.06			-26.07		0.20	0.59		0.01			0.07	0.08	0.02	0.00	0.17
AR17MR-46	AR17MR-45,AR17MR-44,AR17MR-43,AR17MR-42,AR17MR-46	2017-03-25	-25.66380	-60.11595	101	865	5330	340		Depth-integrated				11.005	0.23		0.03		16.49		0.14	0.02		-25.68	0.27		0.88	0.01
AR17MR-06	AR17MR-06	2017-03-12	-26.66087	-58.63467	66	1220			0		6.2	2	10.670		0.30			22.43		0.13			-25.20		0.20	0.83		0.01	0.78	0.01	0.29	0.54	0.14	0.03	1.00
AR17MR-08	AR17MR-08	2017-03-12	-26.66087	-58.63467	66	1220			23		10.9	23	9.830		0.25			25.41		0.10			-25.57		0.20	0.88		0.01			0.21	0.40	0.10	0.02	0.73
AR17MR-07	AR17MR-07	2017-03-12	-26.66087	-58.63467	66	1220			38		7.6	6	10.520		0.27			22.00		0.12			-25.53		0.20	0.84		0.01	0.75	0.02	0.26	0.48	0.12	0.02	0.88
AR17MR-05	AR17MR-05	2017-03-12	-26.66087	-58.63467	66	1220			52		8.7	10	17.070		0.30			18.32		0.16			-25.55		0.20	0.88		0.01			0.26	0.49	0.12	0.02	0.90