U.S. DEPARTMENT OF THE INTERIOR

U.S. GEOLOGICAL SURVEY

Sediment Magnetic and Geochemical Data from Quaternary Lacustrine
Sediments in two Cores from Tule Lake,  Siskyou County, California

by;  Patti J. Best 1, Richard L. Reynolds1, Joseph G. Rosenbaum1, Walter
Dean1, Jeannine Honey1, John Drexler2, and David P. Adam3

Open-file Report 96-293

This report has not been reviewed for conformity with U.S. Geological
Survey editorial standards or with the North American Stratigraphic Code.
Any use of trade, product, or firm names in this report is for descriptive
purposes only and does not imply endorsement by the U.S. Government.

1 U.S. Geological Survey, Denver, Colorado
2 University of Colorado, Boulder, Colorado
3 U.S. Geological Survey, Menlo Park, California

1996

INTRODUCTION

As part of the U.S. Geological Survey's Global Change and Climate History
Program, sediment magnetic and geochemical results have been obtained from
the top 60 meters of lacustrine sediments recovered in two cores from Tule
Lake in northern California.  The sediment magnetic and geochemical data,
presented here in tabular form, complement studies of  diatoms and pollen
in the cores that are the bases for published paleoclimatic
interpretations (Adam and others, 1989; Bradbury, 1991).  Comparisons of
magnetic mineral and geochemical records to the existing climate records
may provide insight into the response of lake-watershed system to climate
change (e.g.,  Rosenbaum and others, 1996).  This report also documents
the methods used to obtain the magnetic properties and geochemical data.
Adam and others (1989) describe the site, the drilling methods, and
lithology of the lacustrine sediments.

METHODS

Sampling (Table 1):  Samples used for magnetic susceptibility and
laboratory induced magnetizations were taken approximately every 5 cm.
Samples, approximately 8 cm3 in volume and representing about 2 cm of
depth in the core, were carved from the core and placed into plastic
bags.  Each such sample was assigned a unique number.  Samples were
transferred from bags into plastic cubes (3.2 cm3 in volume) for magnetic
mineral measurements.  Selected samples were used for geochemical and
sedimentologic analysis.

Magnetic Susceptibility (Table 2):  Volume susceptibility (MS) was
measured using a susceptometer with a sensitivity better than 10-5 volume
SI.  Samples were measured in a 0.1 mT induction at a low frequency of 600
Hz (MSlf) and high frequency of 6000 Hz (MShf). For each sample, the MS
value was determined as the mean of four measurements.  Frequency
dependent susceptibility was calculated as:

FDMS=(MSlf-MShf)/MSlf.

Laboratory Induced Magnetization (Table 2):  A high-speed spinner
magnetometer was used to measure anhysteretic remanent magnetization (ARM)
and isothermal remanent magnetization (IRM).  ARM was imparted in a
decreasing AF from a peak induction of 100 mT and a DC bias of 0.1 mT.
IRM magnetizations were generated at room temperature using an impulse
magnetizer.  Samples were first subjected to IRM in a 1.2T induction (IRM1.
2T.) and were then were then magnetized in the opposite direction using an
induction of 0.3T (IRM -0.3T).  Hard isothermal remanent magnetization (
HIRM) and the S-parameter were calculated as follows (King and Channel,
1991):

HIRM=(IRM1.2T+IRM-0.3T)/2

S=IRM-0.3T/IRM1.2T

Elemental Abundance (Tables 3 and 4):  Elemental abundance were determined
on selected samples using energy dispersive X-ray fluorescence analysis at
the University of Colorado's Department of Geological Sciences.  Abundance
of Cr, Cu, Fe, Mn, Mo, Nb, Ni, Rb, Sr, Ti, V, Y, Zn and Zr were measured.

Total carbon and inorganic (carbonate) carbon were determined using a
coulometer on splits of powdered 1-cm samples of sediment (see Engleman
and others, 1985) (Table 4).  The carbonate in the untreated whole sample
was acidified with perchloric acid to liberate CO2, which was titrated in
the coulometer cell to measure carbonate carbon.  Total carbon was
measured by titrating CO2 liberated during sample combustion at 1050o C in
a stream of oxygen.  The technique has a precision of better than ± 0.5%
for both carbonate and total carbon.  Organic carbon was calculated as the
difference between total and carbonate carbon.

REFERENCES

Adam, D.P.,  Sarna-Wojcicki, A.M., Rieck, H.J., Bradbury, J.P., Dean, W.
E., and Forester, R.M., 1989, Tulelake, California: The last 3 million
years, Palaeogeography, Palaeoclimatology, Palaeoecology: v. 72, p. 89-
103.

Bradbury, J.P., 1991, The late Cenozoic diatom stratigraphy and
paleolimnology of  Tule Lake, Siskyou County, California: Journal of
Paleolimnology, v. 6, p. 205-255.

Engleman,  E.E., Jackson, L.L., Norton, D.R. and Fischer, A. G., 1985,
Determination of carbonate carbon in geological materials by coulometric
titration: Chemical Geology, v. 53, p. 125-128.

King, J.W., and Channel, J.E.T., 1991, Sedimentary magnetism,
environmental magnetism, and magnetostratigraphy:  Reviews of Geophysics,
Supplement, p. 358-370.

Rosenbaum, J.G., Reynolds, R.L., Adam, D.P., Drexler, John, Sarna-
Wojcicki, A.M., and Whitney, G.C., 1996, A middle Pleistocene climate
record from Buck Lake, cascade Range, southern Oregon‹Evidence from
sediment magnetism, trace-element geochemistry, and pollen: Geological
Society of America Bulletin (in press).

Table Captions

TABLE 1.  Sample Numbers and Depths

Tule Lake Sample no.:  A unique sample number used for all measurements.

Core no.:  Identifies core.  Five cores were recovered from Tule Lake.
This document provides data from cores 1 and 2.

Drive no.:  Identifies location in the core.  Each core was divided into
drives numbered sequentially starting with 1 at the top.  Some drives have
been further divided into slugs indicated by letters, starting with A at
the top of the drive.

Drive depth:  The depth in meters of the top of the drive from the top of
the core.   Taken from driller¹s reports.

Sample depth in drive (m):  Midpoint of sample depth interval in meters.

Sample depth in core (m):  Sample depth within drive (m) plus adjusted
depth from top of core.

Adjusted depth in core (m):  The depth in meters of the top of the drive
from the top of the core.  Depths for core 2 have been lowered by 1.17
meters based on the location of the Trego Hot Springs ash located in each
core (see Bradbury, 1991).

Sample density (kg/m3):  Density of sample calculated from the mass of the
dried box samples used in magnetic mineral studies.

TABLE 2.  Sediment Magnetic Data

Sample no.:  A unique sample number used for all measurements.

Core no.:  Core number from which sample was taken.

Depth:   Depth of sample in meters from top of the core.

Adjusted depth:  The adjusted depth in meters from the top of the core.

MSLF:  Low-frequency magnetic susceptibility in m3/kg.

FDMS:  Frequency-dependent magnetic susceptibility in percent.

IRM (1.2T):  Isothermal remanent magnetization from induction in a 1.2
tesla field at room temperature.  Expressed in Am2/kg.

IRM (-.3T):  Isothermal remanent magnetization from induction in a -0.3
tesla field at room temperature.  Expressed in Am2/kg.

S:  (S Ratio) calculated as IRM (-0.3T)/IRM(1.2T).

HIRM: Hard isothermal remanent magnetization: HIRM is calculated as:
[IRM(1.2T) + IRM(-0.3T)]/2 and expressed in Am2/kg.

ARM:  Anhysteretic remanent magnetization in Am2/kg.

TABLE 3.  Elemental Abundances from X-ray Fluorescence

Tule Lake Sample no.:  A unique sample number used for all measurements.
The first number in the sample number refers to the core from which the
sample was taken.

Adjusted depth:  Adjusted depth of sample in meters from top of core.

Elements:  The elements analyzed are listed below.  The units are either
weight percent (Wt%) or parts per million (ppm).

Cr: Chromium-ppm
Cu: Copper-ppm
Fe: Iron- Wt%
Mn: Manganese-ppm
Mo: Molybdenum-ppm
Nb: Niobium-ppm
Ni: Nickel-ppm
Rb: Rubidium-ppm
Sr: Strontium-ppm
Ti: Titanium-Wt %
V:  Vanadium-ppm
Y:  Yttrium-ppm
Zn: Zinc-ppm
Zr: Zirconium-ppm


TABLE 4.  Carbon Abundances

Tule Lake Sample no.:  A unique sample number used for all measurements.
TL1-samples are from core 1; TL-2 samples from core 2.

Adjusted depth:  Adjusted depth of sample in meters from top of core.

Total Carbon:  Percent of carbon (both organic and inorganic) in sample.

Carbonate Carbon:  Percent of inorganic carbon in sample.  Blank entries
indicate that samples were not analyzed for carbonate carbon.  These
samples came from intervals for which previous results (W. Dean,
unpublished data) indicated lack of carbonate carbon.  In the calculation
of organic carbon for these samples, it is assumed that carbonate carbon
is absent.

Organic Carbon:  Percent of organic carbon in sample.  Calculated as total
carbon minus carbonate carbon.