Citation:

PANGAEA.927276

Name: Down-core geochemical data from Disko 2 lake sediment core (West Greenland) collected in April 2013
Published: 2021-01-29
License: https://creativecommons.org/licenses/by/4.0/
Keywords: Arctic; carbon isotope analysis; Disko Island; Greenland; Lake sediment; Organic Geochemistry

Always quote citation above when using data! You can download the citation in several formats below.

RIS Citation BibTeX Citation Text Citation Facebook TwitterShow Map Google Earth

Abstract:

Lake sediment samples were taken in April 2013 from the ice by drilling through lake ice and recovering an undisturbed core using a HON-Kajak sediment corer. Samples were analysed for pigments (University of Nottingham), carbon isotopes and C/N ratios (BGS, Keyworth), lipid biomarkers (Newcastle University) and compound-specific carbon isotopes (CUG, Wuhan). The purpose of the analyses was to develop an environmental reconstruction of carbon cycling for an upland lake (named Disko 2) to encompass the Little Ice Age to recent warming climate periods. Analyses were completed as part of Mark A. Stevenson's PhD research while based at the University of Nottingham, UK (Stevenson, 2017, http://eprints.nottingham.ac.uk/46579).

²¹⁰Pb, ²²⁶Ra, ¹³⁷Cs and ²⁴¹Am concentrations were measured by direct gamma assay in the Environmental Radiometric Facility at University College London (Dr Handong Yang), using an ORTEC HPGe GWL series well-type coaxial low background intrinsic germanium detector. Radiometric dating techniques follow Appleby et al, 1986 (doi: 10.1007/BF00026640), Appleby et al, 1992 (doi:10.1016/0168-583X(92)95328-O) and Appleby, 2001 (doi:10.1007/0-306-47669-X_9) with core extrapolation and linear interpolation used to derive an age depth model to the base of the core. The pigment β-carotene was analysed on an Agilent 1200 series high-performance liquid chromatography (HPLC) using separation conditions outlined in McGowan et al., 2012 (doi:10.1111/j.1365-2427.2011.02689.x). Bulk δ¹³C and C~org~/N ratios were analysed on acidified samples using a Costech ECS4010 elemental analyser (EA) coupled to a VG Triple Trap and a VG Optima dual-inlet mass spectrometer. Key lipid biomarkers (n-alkanes, n-alkanoic acids (as fatty acid methyl esters (FAMEs), n-alkanols and sterols) were analysed using an Agilent 7890A GC coupled to a 5975C MS according to Pearson et al., 2007 (doi:10.1016/j.orggeochem.2007.02.007) and are expressed as ratios, relative to the total of each compound class. Specific ratios were also calculated for CPI 2 n-alkanes (Marzi et al., 1993; doi:10.1016/0146-6380(93)90016-5), terrestrial aquatic ratio (TAR) for n-alkanes (Bourbonniere and Meyers, 1996; doi:10.1007/s002540050074), index of waxy n-alkanes to total hydrocarbons (PWAX) (Zheng et al., 2007; doi:10.1016/j.orggeochem.2007.06.012) and carbon preference index (CPI) for n-alkanoic acids (Matsuda and Koyama, 1977) (doi:10.1016/0016-7037(77)90214-9). Compound-specific δ¹³C on C~28:0~ fatty acid methyl ester (FAME) was analysed using a Thermo Finnigan Trace GC coupled to a Thermo Finnigan Delta Plus XP isotope ratio mass spectrometer using a combustion interface (GC-C-IRMS) according to conditions in Huang et al. (2018; doi:10.1038/s41467-018-03804-w).

Acknowledgements:

Mark Stevenson gratefully acknowledges the receipt of a NERC/ESRC studentship (ES/J500100/1). We acknowledge grants IP-1393-1113 & IP-1516-1114 from the NERC Isotope Geosciences laboratory (NIGL) for the analysis of δ¹³C~org~ & C/N ratios on sediment, soil and plant samples. Lipid and water chemistry analyses were funded by the Freshwater Biological Association's 2015 Gilson Le Cren Memorial Award to Mark Stevenson. We thank Teresa Needham, Christopher Kendrick, Julie Swales, Ian Conway, Graham Morris, Bernard Bowler, Paul Donohoe, Qingwei Song and Jiantao Xue for technical support. We acknowledge the support of Handong Yang for radiometric dating. Financial support for fieldwork was awarded via the INTERACT transnational access scheme (grant agreement No 262693) under the European Community's Seventh Framework Programme and UK RI NERC grant NE/K000276/1. Logistical support is acknowledged from University of Copenhagen Arktisk Station including Ole Stecher, Kjeld Mølgaard and Erik Wille.

Keyword(s):

Arctic; carbon isotope analysis; Disko Island; Greenland; Lake sediment; Organic Geochemistry

Related to:

Stevenson, Mark A; McGowan, Suzanne; Pearson, Emma J; Swann, George E A; Leng, Melanie J; Jones, Vivienne J; Bailey, Joseph J; Huang, Xianyu; Whiteford, Erika (2021): Anthropocene climate warming enhances autochthonous carbon cycling in an upland Arctic lake, Disko Island, West Greenland. Biogeosciences, 18(8), 2465-2485, https://doi.org/10.5194/bg-18-2465-2021

Funding:

Natural Environment Research Council (NERC), grant/award no. ES/J500100/1: NERC/ESRC studentship to Mark Stevenson

Natural Environment Research Council (NERC), grant/award no. NE/K000276/1: UK RI NERC

NERC Isotope Geosciences Laboratory, Keyworth (NIGL), grant/award no. IP-1393-1113

NERC Isotope Geosciences Laboratory, Keyworth (NIGL), grant/award no. IP-1516-1114

Seventh Framework Programme (FP7), grant/award no. 262693 : International Network for Terrestrial Research and Monitoring in the Arctic (INTERACT)

Coverage:

Latitude: 69.389030 * Longitude: -53.401420

Date/Time Start: 2013-04-19T00:00:00 * Date/Time End: 2013-04-19T00:00:00

Minimum DEPTH, sediment/rock: 0.0000 m * Maximum DEPTH, sediment/rock: 0.3125 m

Event(s):

D2-K1-2013 * Latitude: 69.389030 * Longitude: -53.401420 * Date/Time: 2013-04-19T00:00:00 * Elevation: -575.0 m * Location: Disko Bay, Greenland * Method/Device: HON-Kajak sediment corer (HONK)

Comment:

± errors derived from counting statisitcs. The absolute efficiencies of the detector were determined using calibrated sources and sediment samples of known activity. See Appleby et al, 1986 (doi:10.1007/0-306-47669-X), Appleby et al, 1992 (doi:10.1016/0168-583X(92)95328-O) and Appleby, 2001 (doi:10.1007/BF00026640).

Parameter(s):

#	Name	Short Name	Unit	Principal Investigator	Method/Device	Comment
1	DEPTH, sediment/rock	Depth sed	m	Stevenson, Mark A		Geocode
2	Depth, top/min	Depth top	m	Stevenson, Mark A
3	Depth, bottom/max	Depth bot	m	Stevenson, Mark A
4	Dry mass per area	Dry m area	g/cm²	Stevenson, Mark A	Calculated
5	Lead-210	210Pb	Bq/kg	Stevenson, Mark A	Reverse Coaxial Radiation Detector, ORTEC, HPGe GWL
6	Lead-210, error	210Pb e	±	Stevenson, Mark A	Reverse Coaxial Radiation Detector, ORTEC, HPGe GWL
7	Lead-210, supported	210Pb sup	Bq/kg	Stevenson, Mark A	Reverse Coaxial Radiation Detector, ORTEC, HPGe GWL
8	Lead-210, supported, error	210Pb sup e	±	Stevenson, Mark A	Reverse Coaxial Radiation Detector, ORTEC, HPGe GWL
9	Lead-210, unsupported	210Pb unsup	Bq/kg	Stevenson, Mark A	Reverse Coaxial Radiation Detector, ORTEC, HPGe GWL
10	Lead-210, unsupported, error	210Pb unsup e	±	Stevenson, Mark A	Reverse Coaxial Radiation Detector, ORTEC, HPGe GWL
11	Lead-210, unsupported, cumulative	210Pb unsup cum	Bq/m²	Stevenson, Mark A	CRS model (Constant Rate of Supply)
12	Lead-210, unsupported, cumulative, error	210Pb unsup cum e	±	Stevenson, Mark A	CRS model (Constant Rate of Supply)
13	Caesium-137	137Cs	Bq/kg	Stevenson, Mark A	Reverse Coaxial Radiation Detector, ORTEC, HPGe GWL
14	Caesium-137, error	137Cs e	±	Stevenson, Mark A	Reverse Coaxial Radiation Detector, ORTEC, HPGe GWL
15	Americium-241	241Am	Bq/kg	Stevenson, Mark A	Reverse Coaxial Radiation Detector, ORTEC, HPGe GWL
16	Americium-241, error	241Am e	±	Stevenson, Mark A	Reverse Coaxial Radiation Detector, ORTEC, HPGe GWL
17	Age	Age	a AD/CE	Stevenson, Mark A	CRS model (Constant Rate of Supply)
18	Age	Age	a	Stevenson, Mark A	CRS model (Constant Rate of Supply)
19	Age, standard error	Age std e	±	Stevenson, Mark A	CRS model (Constant Rate of Supply)
20	Accumulation rate per year	Acc rate	g/cm²/a	Stevenson, Mark A	CRS model (Constant Rate of Supply)
21	Sedimentation rate per year	SR	cm/a	Stevenson, Mark A	CRS model (Constant Rate of Supply)
22	Sedimentation rate, error	SR e	±	Stevenson, Mark A	CRS model (Constant Rate of Supply)
23	Age	Age	a AD/CE	Stevenson, Mark A	CRS model (Constant Rate of Supply)
24	Accumulation rate, dry mass	DMAR	g/cm²/a	Stevenson, Mark A	CRS model (Constant Rate of Supply)
25	Accumulation rate, carbon, per year	Acc rate C	g/m²/a	Stevenson, Mark A	CRS model (Constant Rate of Supply)	CMAR
26	Carbon, organic, total	TOC	%	Stevenson, Mark A	Element analyser CHN (ECS4010, Costech) coupled to a VG Triple Trap and a VG Optima dual-inlet mass spectrometer (MS)
27	δ13C, organic carbon	δ13C Corg	‰ PDB	Stevenson, Mark A	Element analyser CHN (ECS4010, Costech) coupled to a VG Triple Trap and a VG Optima dual-inlet mass spectrometer (MS)
28	Carbon/Nitrogen ratio	C/N		Stevenson, Mark A	Element analyser CHN (ECS4010, Costech) coupled to a VG Triple Trap and a VG Optima dual-inlet mass spectrometer (MS)
29	beta-Carotene, per unit mass total organic carbon	b-Car/TOC	nmol/g	Stevenson, Mark A	High performance liquid chromatography (HPLC), Agilent 1200
30	Carbon Preference Index 2, n-Alkanes ((C23+C25+C27 )+(C25+C27+C29))/2*(C24+C26+C28)	CPI 2		Stevenson, Mark A	Calculation according to Marzi et al. (1993)
31	Terrigenous/aquatic ratio	TAR		Stevenson, Mark A	Calculated after Bourbonniere and Meyers, 1996: (C27+C29+C31)/(C15+C17+C19)
32	Index of waxy n-alkanes to total hydrocarbons (C27+C29+C31)/(C23+C25+C29+C31)	Pwax		Stevenson, Mark A	Calculated after Zheng et al., 2007
33	n-alkane C27/sum n-alkanes	C27/tot n-alk		Stevenson, Mark A	Coupled gas chromatography/mass spectrometry (GC/MS) on an Agilent Technologies 7890A GC linked to 5795C MS triple axis mass detector, equipped with a HP DB5-MS column
34	Carbon Preference Index, n-Alkanoic acids	CPI n-Alk Acid		Stevenson, Mark A	Calculated after Matsuda and Koyama, 1977: 0.5*((C12+C14+C16)+(C22+C24+C26+C28+C30))+((C14+C16+C18)+(C24+C26+C28+C30+C32))/((C13+C15+C17)+(C23+C25+C27+C29 +C31))
35	n-Alkanoic acid C30/sum n-Alkanoic acid ratio	C30/tot FAME		Stevenson, Mark A	Coupled gas chromatography/mass spectrometry (GC/MS) on an Agilent Technologies 7890A GC linked to 5795C MS triple axis mass detector, equipped with a HP DB5-MS column
36	n-Alkanol C16/sum n-Alkanols	C16/tot n-A.ol		Stevenson, Mark A	Coupled gas chromatography/mass spectrometry (GC/MS) on an Agilent Technologies 7890A GC linked to 5795C MS triple axis mass detector, equipped with a HP DB5-MS column
37	n-Alkanol C24/sum n-Alkanols	C24/tot n-A.ol		Stevenson, Mark A	Coupled gas chromatography/mass spectrometry (GC/MS) on an Agilent Technologies 7890A GC linked to 5795C MS triple axis mass detector, equipped with a HP DB5-MS column
38	24-Methylcholesta-5,22E-dien-3beta-ol/sum sterols	Brassicasterol/ tot sterol		Stevenson, Mark A	Coupled gas chromatography/mass spectrometry (GC/MS) on an Agilent Technologies 7890A GC linked to 5795C MS triple axis mass detector, equipped with a HP DB5-MS column
39	n-Alkanoic acid C28:0, δ13C	FAME C28:0 δ13C	‰ PDB	Stevenson, Mark A	Thermo Trace GC coupled to ThermoFinnigan DELTAplus XP (GC-C-IRMS)

License:

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

Size:

1040 data points

Data

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

1 Depth sed [m]	2 Depth top [m]	3 Depth bot [m]	4 Dry m area [g/cm²] (Calculated)	5 210Pb [Bq/kg] (Reverse Coaxial Radiation Det...)	6 210Pb e [±] (Reverse Coaxial Radiation Det...)	7 210Pb sup [Bq/kg] (Reverse Coaxial Radiation Det...)	8 210Pb sup e [±] (Reverse Coaxial Radiation Det...)	9 210Pb unsup [Bq/kg] (Reverse Coaxial Radiation Det...)	10 210Pb unsup e [±] (Reverse Coaxial Radiation Det...)	11 210Pb unsup cum [Bq/m²] (CRS model (Constant Rate of S...)	12 210Pb unsup cum e [±] (CRS model (Constant Rate of S...)	13 137Cs [Bq/kg] (Reverse Coaxial Radiation Det...)	14 137Cs e [±] (Reverse Coaxial Radiation Det...)	15 241Am [Bq/kg] (Reverse Coaxial Radiation Det...)	16 241Am e [±] (Reverse Coaxial Radiation Det...)	17 Age [a AD/CE] (CRS model (Constant Rate of S...)	18 Age [a] (CRS model (Constant Rate of S...)	19 Age std e [±] (CRS model (Constant Rate of S...)	20 Acc rate [g/cm²/a] (CRS model (Constant Rate of S...)	21 SR [cm/a] (CRS model (Constant Rate of S...)	22 SR e [±] (CRS model (Constant Rate of S...)	23 Age [a AD/CE] (CRS model (Constant Rate of S...)	24 DMAR [g/cm²/a] (CRS model (Constant Rate of S...)	25 Acc rate C [g/m²/a] (CMAR, CRS model (Constant Rat...)	26 TOC [%] (Element analyser CHN (ECS4010...)	27 δ13C Corg [‰ PDB] (Element analyser CHN (ECS4010...)	28 C/N (Element analyser CHN (ECS4010...)	29 b-Car/TOC [nmol/g] (High performance liquid chrom...)	30 CPI 2 (Calculation according to Marz...)	31 TAR (Calculated after Bourbonniere...)	32 Pwax (Calculated after Zheng et al....)	33 C27/tot n-alk (Coupled gas chromatography/ma...)	34 CPI n-Alk Acid (Calculated after Matsuda and ...)	35 C30/tot FAME (Coupled gas chromatography/ma...)	36 C16/tot n-A.ol (Coupled gas chromatography/ma...)	37 C24/tot n-A.ol (Coupled gas chromatography/ma...)	38 Brassicasterol/ tot sterol (Coupled gas chromatography/ma...)	39 FAME C28:0 δ13C [‰ PDB] (Thermo Trace GC coupled to Th...)
0.0000	0.00	0.00														2013	0
0.0025	0.00	0.05	0.04	856.88	36.35	15.04	7.05	841.84	37.03	382.5	22.3	70.66	5.44	0.00	0.00	2010	3	2	0.0137	0.071	7.2	2010	0.012	8.5	7.4	-26.7	7.6	24.1	2.4	5.1	0.8	6.0	24.2	0.1	16.7	10.8	0.6087	-33.1
0.0075	0.05	0.10																				2003	0.017	9.3	5.6	-27.5	7.5	70.4	4.4	7.9	0.8	12.6	19.8	0.6	12.3	15.6	0.6548	-35.6
0.0125	0.10	0.15	0.24	594.05	38.51	20.97	6.62	573.08	39.07	1774.6	94.5	105.84	6.83	5.63	2.50	1995	18	2	0.0126	0.063	10.4	1995	0.008	4.2	5.1	-27.7	7.5	24.8
0.0175	0.15	0.20																				1987	0.015	6.7	4.4	-27.6	7.5	47.6
0.0225	0.20	0.25	0.44	388.20	28.19	2.94	5.28	385.26	28.68	2727.2	129.2	109.41	5.97	0.00	0.00	1978	35	3	0.0111	0.058	14.5	1978	0.010	4.5	4.6	-27.6	7.7	15.4
0.0275	0.25	0.30	0.53	305.44	16.93	8.52	3.34	296.92	17.26	3019.9	133.6	145.24	4.11	3.70	1.31	1970	43	4	0.0113	0.062	16.7	1970	0.011	4.5	4.1	-27.4	8.3	34.1
0.0325	0.30	0.35	0.63	180.74	21.44	17.21	5.08	163.53	22.03	3231.7	135.1	148.11	5.79	4.66	2.04	1963	50	5	0.0220	0.100	23.6	1963	0.014	6.2	4.3	-27.4	8.6	38.1	3.7	5.8	0.7	13.6	16.9	0.4	5.0	17.9	0.4253	-29.5
0.0375	0.35	0.40	0.75	212.60	14.21	12.32	2.77	200.28	14.48	3454.5	137.6	121.72	3.69	4.60	1.22	1960	53	5	0.0300	0.125	8.4	1960	0.048	20.1	4.2	-27.5	9.3	54.0
0.0425	0.40	0.45	0.86	188.16	16.98	11.08	3.98	177.08	17.44	3674.0	139.2	95.22	4.09	4.65	1.44	1955	58	5	0.0250	0.107	10.8	1955	0.018	7.9	4.4	-27.7	10.1	19.5
0.0475	0.45	0.50																				1951	0.030	15.0	5.0	-27.8	10.0	38.3
0.0525	0.50	0.55	1.09	152.54	13.73	12.48	3.63	140.06	14.20	4036.9	144.2	52.56	2.83	0.00	0.00	1946	67	5	0.0230	0.100	11.3	1946	0.023	9.8	4.3	-27.9	10.3	14.4	3.7	4.1	0.6	10.4	17.1	0.6	3.0	14.8	0.2329
0.0575	0.55	0.60	1.22	139.77	12.59	12.78	2.58	126.99	12.85	4198.6	145.8	36.60	2.29	0.00	0.00	1940	73	5	0.0250	0.083	11.6	1940	0.023	9.4	4.0	-28.0	10.3	22.2
0.0625	0.60	0.65	1.39	92.51	10.20	15.14	2.87	77.37	10.60	4374.0	147.4	12.51	1.50	0.00	0.00	1934	79	6	0.0230	0.059	15.0	1934	0.035	12.3	3.5	-27.8	10.9	18.0
0.0675	0.65	0.70	1.61	74.92	9.19	8.22	2.06	66.70	9.42	4531.4	149.2	9.89	1.22	0.00	0.00	1923	88	6	0.0220	0.050	15.7	1923	0.021	6.4	3.1	-25.9	12.4	0.8
0.0725	0.70	0.75	1.83	73.93	5.81	11.77	1.31	62.16	5.96	4676.2	150.6	7.41	0.77	0.00	0.00	1914	98	6	0.0240	0.056	13.1	1914	0.025	6.7	2.7	-26.5	9.9	5.1
0.0775	0.75	0.80	2.04	48.42	7.10	11.90	1.57	36.52	7.27	4775.2	151.2	8.43	1.04	0.00	0.00	1905	108	7	0.0210	0.053	22.6	1905	0.021	5.0	2.4	-24.5	11.0	0.9
0.0825	0.80	0.85	2.23	49.37	6.34	13.01	1.54	36.36	6.52	4845.7	151.9	5.64	0.85	0.00	0.00	1895	118	8	0.0180	0.043	22.3	1895	0.020	4.5	2.2	-23.5	10.2	1.2	4.1	10.5	0.5	11.7	11.0	0.9	1.9	18.1	0.1157	-26.3
0.0875	0.85	0.90	2.44	38.35	5.44	10.56	1.32	27.79	5.60	4913.0	152.5	3.44	0.73	0.00	0.00	1882	131	10	0.0140	0.033	27.3	1882	0.017	4.3	2.5	-24.6	11.4	0.8
0.0925	0.90	0.95	2.66	30.13	4.70	12.67	1.19	17.46	4.85	4960.0	153.0	1.87	0.60	0.00	0.00	1865	148	12	0.0120	0.027	39.5	1865	0.012	2.7	2.3	-23.8	10.2	0.8
0.0975	0.95	1.00	2.88	19.41	4.30	11.46	1.05	7.95	4.43	4986.7	153.3	2.21	0.54	0.00	0.00	1845	168	18	0.0110	0.025	45.5	1845	0.012	2.1	1.7	-24.1	10.3	1.8
0.1025	1.00	1.05																				1833	0.017	3.7	2.2	-23.5	10.2	2.3	3.7	13.4	0.6	13.5	9.1	2.0	2.2	16.6	0.1165
0.1075	1.05	1.10																				1821	0.019	4.3	2.3	-22.8	10.0	1.0
0.1125	1.10	1.15																				1809	0.021	4.7	2.2	-22.8	9.7	0.9
0.1175	1.15	1.20																				1798	0.019	4.6	2.4	-22.4	9.6	4.2	4.1	20.2	0.6	15.2	8.0	2.6	1.7	16.8	0.0966	-24.5
0.1225	1.20	1.25																				1786	0.023	4.4	1.9	-22.8	9.5	1.0
0.1275	1.25	1.30																				1774	0.020	3.3	1.7	-23.0	8.8	0.0
0.1325	1.30	1.35																				1762	0.022	4.6	2.1	-22.5	10.4	0.8	4.3	30.6	0.6	16.6	9.4	1.1	2.6	17.8	0.0972
0.1375	1.35	1.40																				1750	0.025	4.8	1.9	-22.5	8.8	1.1
0.1425	1.40	1.45																				1738	0.025	5.8	2.4	-22.5	9.9	3.9	3.9	15.5	0.6	14.4	9.1	1.3	2.0	16.3	0.0921	-24.1
0.1475	1.45	1.50																				1726	0.023	5.1	2.3	-22.1	9.5	1.0
0.1525	1.50	1.55																				1714	0.024	5.6	2.4	-22.1	9.4	1.3	3.8	14.5	0.6	13.6	10.9	1.5	2.7	15.2	0.1078	-25.3
0.1575	1.55	1.60																				1703	0.023	6.0	2.5	-21.6	10.0	0.9
0.1625	1.60	1.65																				1691	0.021	4.8	2.3	-21.7	9.8	2.6
0.1675	1.65	1.70																				1679	0.025	5.7	2.3	-22.0	9.4	0.8	5.3	8.7	0.5	14.1	10.0	1.6	3.1	15.1	0.0979	-22.8
0.1725	1.70	1.75																				1667	0.013	5.2	3.9	-21.1	9.3	13.9
0.1775	1.75	1.80																				1655	0.014	5.5	4.0	-20.5	9.3	11.1
0.1825	1.80	1.85																				1643	0.013	7.1	5.3	-20.2	9.9	24.1	6.3	6.7	0.4	11.3	8.9	1.9	4.0	15.1	0.0984
0.1875	1.85	1.90																				1631	0.016	6.4	4.0	-20.9	9.5	1.1
0.1925	1.90	1.95																				1619	0.018	5.7	3.1	-21.7	9.5	2.3	5.4	9.6	0.5	12.5	6.9	3.0	5.2	11.1	0.1118	-23.2
0.1975	1.95	2.00																				1608	0.017	5.8	3.3	-21.4	9.6	1.0
0.2025	2.00	2.05																				1596	0.019	6.8	3.5	-21.4	9.2	1.5	4.1	15.4	0.7	15.1	9.2	1.8	2.2	16.2	0.1017	-25.3
0.2075	2.05	2.10																				1584	0.017	5.6	3.2	-21.2	9.1	6.4
0.2125	2.10	2.15																				1572	0.018	6.3	3.6	-21.2	9.5	4.6
0.2175	2.15	2.20																				1560	0.020	6.6	3.3	-21.0	9.0	1.1	4.4	9.8	0.6	13.6	10.3	1.6	2.6	16.2	0.1018	-23.9
0.2225	2.20	2.25																				1548	0.025	5.1	2.0	-22.9	9.6	2.4
0.2275	2.25	2.30																				1536	0.024	4.1	1.7	-23.4	9.7	0.5
0.2325	2.30	2.35																				1524	0.031	5.5	1.8	-23.8	10.3	1.1
0.2375	2.35	2.40																				1513	0.036	4.9	1.4	-24.1	12.0	3.9
0.2425	2.40	2.45																				1501	0.028	4.6	1.6	-23.9	10.0	1.4
0.2475	2.45	2.50																				1489	0.020	4.3	2.1	-22.9	9.4	1.8
0.2525	2.50	2.55																				1477	0.028	5.7	2.1	-22.6	9.3	9.5
0.2575	2.55	2.60																				1465	0.022	5.4	2.4	-22.3	9.6	7.0
0.2625	2.60	2.65																				1453	0.019	5.3	2.8	-22.0	10.2	12.9
0.2675	2.65	2.70																				1441	0.014	7.8	5.7	-20.3	9.1	26.5
0.2725	2.70	2.75																				1429	0.027	7.5	2.8	-21.7	9.1	19.8
0.2775	2.75	2.80																				1418	0.024	5.2	2.2	-22.5	9.2	1.0
0.2825	2.80	2.85																				1406	0.014	3.8	2.8	-21.9	9.0	21.0
0.2875	2.85	2.90																				1394	0.020	4.8	2.5	-22.6	9.5	3.1
0.2925	2.90	2.95																				1382	0.032	5.2	1.6	-23.3	9.0	2.1
0.2975	2.95	3.00																				1370	0.014	3.5	2.6	-22.2	9.1	0.8
0.3025	3.00	3.05																				1358	0.020	5.2	2.6	-22.3	10.4	7.8
0.3075	3.05	3.10																				1346	0.024	6.7	2.8	-22.1	10.3	11.2
0.3125	3.10	3.15																				1334	0.017	5.1	3.1	-21.1	9.5	33.4