anomalously nigo rare - earth element abundances in hawaiian lavas

ANALYTICAL

ANOMALOUSLY NIGO RARE - EARTH ELEMENT ABUNDANCES IN HAWAIIAN LAVAS R. V. Fodor Department of Marine, Earth, and Atmospheric Sciences North Carolina State University Raleigh, NC 27695-8208

Gábor Dobosi Geochemical Research Hungarian Academy of Sciences Budapest, Hungary 1112

G. R. Bauer Department of Land and Natural Resources Division of Water Resource Management Honolulu, HI 96813

The compositions of the lavas that comprise the Hawaiian Islands are often used as models for understanding volcanism and the chemical characteristics of oceanic volcanoes. From a chemical viewpoint, Hawaii is an ideal paradigm because of its location far from continental crust. Hawaii's oceanic setting tells us that the magmas t h a t erupted as lavas to cons t r u c t t h e i s l a n d s did n o t p a s s through potentially contaminating material. Chemical compositions of H a w a i i a n l a v a s , t h e r e f o r e , completely r e p r e s e n t the source from which they were derived: peridotite rock of the upper mantle. Chemical and isotopic analyses of Hawaiian volcanic rocks have become routine laboratory procedures. In the interpretation and modeling of data for a suite of rocks, we often focus on 0003-2700/92/0364-639A/$02.50/0 © 1992 American Chemical Society

the significance of the abundance of certain trace elements, such as Zr, Nb, Th, and Ce, and on the importance of isotope ratios, such as 8 7 Sr/ 86 Sr, which may vary by < 0.00005 from one sample to another. The objectives of these analytical studies include the identification of some geologically important characteristics of the Earth, such as the chemical nature of the upper mantle beneath each volcano, compositional changes in the mantle during volcano construction, and the chemically and isotopically varied m a n t l e components t h a t may have mixed before and during magma generation. Another objective is to define the processes by which m a g m a s c h a n g e composition during storage in subvolcano reservoirs before eruption. D u r i n g the 1980s n u m e r o u s geochemists and igneous petrologists produced highly refined models for Kauai Niihau

Oahu

Lanai

Molokai Maui

mmrm

Hawaii

Hawaiian magmatism. However, information from new chemical studies of Hawaiian lavas is not always compatible with existing models. In this article we will discuss one such study of a suite of lavas from the island of Kahoolawe t h a t contain r a r e - e a r t h element a b u n d a n c e s unlike those ever expected for Hawaiian volcanic rocks.

Chemical characteristics of lavas The lavas of the 15 volcanoes of the eight major islands (Niihau, Kauai, Oahu, Molokai, Lanai, Kahoolawe, Maui, and Hawaii) originated as basalt composition magmas produced by partial melting of the mantle. The melting occurred at depths of - 6 0 90 km. Over the past 5 million years, the m a g m a s erupted to construct broad, shield-like volcanoes reaching far above the sea floor to form the Hawaiian Islands. In their sampling of the island lavas, geologists and geochemists note the s t r a t i g r a p h i e positions of the samples on the volcanoes—whether they represent the main body of the volcano, the shield edifice, lavas that filled a caldera at the summit of the volcano, or other features such as small cones made of cinders or spatter that may mark the final eruptions of a volcano. Hundreds of analyses of Hawaiian volcanic rocks have established the detailed chemical makeup of the in-

ANALYTICAL CHEMISTRY, VOL. 64, NO. 11, JUNE 1, 1992 · 639 A

ANALYTICAL APPROACH dividual volcanoes a n d helped to characterize their mantle source material. The rare-earth elements are an important part of these evaluations. Particularly valuable is t h e geochemical behavior of r a r e - e a r t h elements during the partial melting of peridotite rock to form basaltic magmas and during crystallization of those magmas to form basaltic rocks. For example, because heavy r a r e earth elements (Yb and Lu) preferentially partition into certain minerals, the role of a mantle phase such as garnet in the production of basalt can be evaluated from the rare-earth element content in lavas. Also, because light r a r e - e a r t h elements (La and Ce) have different compatibility with crystallizing basaltic minerals t h a n do middle (Eu) and heavy rare-earth elements, we can determine the type and amount of minerals that crystallized in basaltic magma during volcano development. Rare-earth elements in lavas To decipher geochemical signatures and to improve petrogenetic (rock origin) models for ocean island volcanism, r a r e - e a r t h element abundances are determined in all newly collected suites of Hawaiian lavas. Data are acquired primarily by using neutron activation analysis (NAA). The eight rare-earth elements La, Ce, Nd, Sm, Eu, Tb, Yb, and Lu are usually determined as a set for basaltic rock. Typically, the concentrations (in parts per million) are norm a l i z e d t o a v e r a g e v a l u e s for chondritic meteorites and plotted as rare-earth element patterns (Figure 1). Normalizing the d a t a to chondrites provides reference to material that approximates the earth's mantle composition. It also enables one to graphically compare rare-earth element concentrations among different rocks by eliminating the Oddo-Harkins effect of higher concentrations for elements with even atomic numbers. The patterns for various compositional types of Hawaiian lavas have been characterized (1) and can be reasonably well predicted for a particular rock after its major element composition is determined. In light of this, we believed that our geochemical investigation of Kahoolawe Island would be fairly routine and the trace element compositions somewhat predictable. Kahoolawe Island Prior to our work, Kahoolawe Island was the only Hawaiian volcano that

had not been studied geochemically. It is managed by the U.S. military, and access is restricted. Our collection of ~ 200 samples was obtained with permission from U.S. Navy personnel at Pearl Harbor. Providing helicopter transportation and demolition experts who escorted us to ensure our safety, the Navy allowed u s to comb the island. Our first assessment of Kahoolawe basaltic rocks (2) yielded some lava rare-earth element abundances t h a t were d r a m a t i c a l l y different from those expected. These rock samples were collected from lava vents that represent t h e last episodes of Kahoolawe volcanism. Many rocks were enriched with a greater r a r e - e a r t h element content than that found in other Hawaiian lavas, including the main shield lavas of Kahoolawe (Figure la). For example, the concentration of La, which would typically be 1 3 - 1 5 ppm in the basaltic rocks examined, was 100-200 ppm. The

(a) Enriched lavas

Typical shield lava

Atomic number (b) Highly enriched

Normal Slightly enriched

Atomic number

Figure 1. Patterns obtained using NAA. (a) Rare-earth element patterns for a typical shield lava and for two rare-earth element- and Y-enriched lavas of Kahoolawe Island. Star indicates a negative Ce anomaly, (b) Rare-earth element patterns for four samples from different parts of the same lava flow on Kahoolawe. The pattern labeled "normal" is for a portion of lava believed to be free of rare-earth element and Y enrichment. The great differences in rare-earth element abundances (from "normal" to "highly enriched") indicate that the rare-earth element abundances are not evenly distributed throughout the lava. Patterns are constructed by dividing part-per-million values for the lavas by the average rare-earth element abundances of chondritic meteorites.

640 A · ANALYTICAL CHEMISTRY, VOL. 64, NO. 11, JUNE 1, 1992

rocks with high rare-earth element abundances also had unusually high Y concentrations—in one case, up to five times greater than expected. Additionally, some Kahoolawe lavas had low Ce abundances relative to the high amounts of the remaining r a r e - e a r t h elements studied. Such occurrences of comparatively low Ce are referred to as negative Ce anomalies (Figure la). The anomalously high rare-earth elements and Y values were particularly intriguing because Kahoolawe had been a bombing target for the U.S. Navy since World War II. The lengthy history of bombing made us wonder whether the unusual r a r e earth element and Y concentrations were related to trace elements in explosives. However, a recent publication (3) citing a lava on Oahu with similar r a r e - e a r t h element a n d Y concentrations dissuaded u s from pursuing this hypothesis.

Possible explanations for rare-earth element and Y enrichments We were left with three alternative geochemical hypotheses. The first was that the upper mantle contains a r a r e phase t h a t is enriched w i t h rare-earth elements and Y and occasionally is included in the partial m e l t i n g t h a t produces H a w a i i a n magmas. The second theory involved assimilation of some unusual rareearth element/Y-bearing material (perhaps from the marine environment) by some of the magmas as they ascended from the mantle to the surface. Finally, we considered secondary processes such as surface weathering and exposure to hydrothermal solutions. We gave this idea lowest priority because the rocks in question did not appear to be weathered or altered, or to have been exposed to hydrothermal activity. Furthermore, r a r e - e a r t h elements and Y are not necessarily mobilized in rocks and concentrated elsewhere during the commonly observed geologic p r o cesses. We also found problems with the first two hypotheses. The rare-earth element and Y abundances of the anomalously enriched rocks did not vary systematically with other trace elements in geochemically similar rocks, nor did the r a r e - e a r t h elem e n t s vary systematically among themselves. This suggested t h a t a single, special m a n t l e phase t h a t melted to yield rare-earth element/ Y-enriched magmas had not existed. Because the rocks were not enriched

SWAGELOK® Tube Fittings in elements likely to be abundant in a seawater environment, such as Sr and Mn, we discarded the idea of as­ similated r a r e - e a r t h element/Ybearing marine material before erup­ tion.

...your widest selection of* sizes, shapes, and materials • leak-tight performance, low in-service cost • fractional sizes 1/16" to 2" • metric sizes 2mm to 25mm (male and female connectors available in tube to NPT or BSP/ISO threads) • all machinable metals and plastics • locally available from Authorized Sales & Service Representatives

Identifying the rare-earth element/ Y-bearing phase The key to finding the origin of the r a r e - e a r t h element and Y enrich­ ment in the basalts was to determine how these elements were contained. That is, which basalt mineral phases housed high amounts of rare-earth elements and Y, and how did they oc­ cur in the rocks? Was it a phenocryst phase (mineral grain visible without magnification), or was it microscopic and hidden in the groundmass of the basalts? Our detailed microscopic ex­ amination of the rare-earth element/ Y-rich samples had revealed nothing special about their mineral assem­ blages. All observed phases had been expected to be present in these rocks. We decided t h a t electron microprobe analysis would be ideal for lo­ cating the phase because we would be able to scan the sample using an electron beam while the detectors were optimized for r a r e - e a r t h ele­ ments and Y. By viewing the sample during investigation, the slightest hint of La or Y X-rays created by the beam falling on a r a r e - e a r t h ele­ ment/Y-rich phase would reveal the location of the phase in the rock. This method of examination could not, however, be done using the stan­ dard procedure for mineral analysis (using a l-3-μπι electron beam), be­ cause the chances were small for lo­ cating a phase t h a t may be only micrometers in size. The investiga­ tion required optimizing the spec­ trometers for La and Y, enlarging the electron beam to a - 200-μπι diame­ ter, and scanning a polished speci­ men of r a r e - e a r t h e l e m e n t / Y - en­ riched lava until a La or Y signal was detected. The search was completed in seconds. The groundmass of the lava sample examined was rich with 1 0 - 3 0 ^ m - s i z e d grains hidden amid the normal assemblage of pyroxene, plagioclase, and F e - T i oxides. F r o m t h a t p o i n t on, we d r e w sketches of all the located rare-earth element/Y-rich grains and the sur­ rounding fields of view of the speci­ men as we saw them through the mi­ croprobe optical system. These sketches would help us later locate and study the rare-earth element/Yrich phases with the aid of a polariz­ ing microscope. Optical microscopy revealed irreg-

Male Connector

Union Tee

SAE/MS Positionable Male Elbow

Bulkhead Male Connector

SAE/MS Male Connector

Union

Male Elbow

Cross SAE/MS Positionable Male Run Tee

SWAGELOKIoMUnlon

45° Male Elbow

SWAGELOK lo AN Bulkhead Union

45° SAE/MS Positionable Male Elbow

Male Run Tee

Reducer

Male Branch Tee

SAE/MS Positional) le Male Branch Tee

Bulkhead Reducer

Cap

Plug

Female Connector SWAGtLOK 10 AN Adapter Heat Exchanger

Tee Bulkhead Female Connector Port Connector

Bore-Through Male Connector Used As Thermocouple Connector

Female Elbow Reducing Port Connector

Female Run Tee

KN Tube Fittings For Use on Polyethylene Tubing

SWAGELOKtoTube Socket Welb Union SWAGELOK ID Tube Sockel Weld Elbow

CHROMATOGRAPH FITTINGS Female Branch Tee

SWAGELOK to Male Pipe Weld Connector

SWAGELOK to Male Pipe Weld Elbow

Union

Union Union Tee O-Seal Male Connector Pipe Thread

Reducing Union

O-Seal Straight Thread Connector Zero Volume Column End Fitting Bulkhead Union g) 1989 SWAGELOK Co., all rights reserved PF 2 087

Union Elbow

TUBE

FITTINGS

SWAGELOK 10 Female SWAGELOK Union

SWAGELOK Co., Solon, Ohio 44139 / SWAGELOK Canada Ltd., Ontario CIRCLE 125 ON READER SERVICE CARD

ANALYTICAL CHEMISTRY, VOL. 64, NO. 11, JUNE 1, 1992 · 641 A

ANALYTICAL APPROACH the island, the same lava flow con­ t a i n e d r a r e - e a r t h element and Y c o n t e n t s r a n g i n g from n o r m a l to highly enriched levels for basaltic rocks (Figure lb). This was signifi­ cant because it indicated t h a t the high rare-earth element and Y con­ centrations were not part of the orig­ inal magma system. Had they been, the concentrations would be homoge­ neous in the lavas representing the magmas. Instead, the sporadic traceelement e n r i c h m e n t s in the lavas most likely developed after the lavas h a d cooled to rock (-1.15 million years ago). This observation was consistent with how the rare-earth element/Y b e a r i n g m a t e r i a l occurred in t h e rocks as especially small groundmass g r a i n s . F u r t h e r m o r e , t h e groundmass sites support the means of orig­ ination by secondary processes such as weathering. Our documentation of this unusual Hawaiian geochemical feature neces­ s i t a t e d q u a n t i t a t i v e a n a l y s e s for identification and visual character­ izations of the phases. To acquire

ularly shaped, high-relief, somewhat fibrous-looking grains. We were un­ familiar with the properties of this p h a s e as viewed u n d e r polarized light, but the examination neverthe­ less provided an u n d e r s t a n d i n g of how certain Kahoolawe basaltic la­ vas served as hosts to high r a r e earth element and Y levels. We could then place the lava sample back into the electron microprobe for quantita­ tive determination of the material previously u n k n o w n in H a w a i i a n volcanic rocks. Enrichment by secondary processes Concurrent with our research, F. A. Frey of the Massachusetts Institute of Technology performed neutron ac­ tivation rare-earth element analysis of additional samples from the same lava that we were examining with an electron microprobe. The NAA r e ­ sults showed t h a t the anomalous r a r e - e a r t h element and Y abun­ dances were not evenly distributed throughout the lava. Examined from various places on

Backscattered electron image

Ρ

Nd

these, we used an electron microprobe with wavelength-dispersive spectrometers and the capability to do backscattered electron scanning imaging and X-ray mapping. These techniques provided grain size mea­ surements and grain shapes along with element distribution maps of the groundmasses. We thus under­ stood how the rare-earth element/Y rich phase was texturally i n t e r r e ­ lated with the groundmass mineral assemblages (Figure 2). To our surprise, the electron mi­ croprobe analyses revealed a phos­ phate with 32.4 wt % P 2 0 5 and sev­ eral percent each of La, Ce, Nd, and Y oxides (see box below). The pattern in Figure 3 illustrates the high con­ centration of rare-earth elements in this phase compared with that of the host lava (2). Although no published analyses of phosphates were identi­ cal to our values, some values for the rare-earth element/Y-bearing phos­ phate phase known as rhabdophane were close to the composition we de­ t e r m i n e d for o u r p h a s e . R h a b ­ dophane has seldom been reported in the literature, but the available in­ formation pointed to its origin by secondary mineralization. This indi­ cated t h a t surface weathering pro­ cesses most likely accounted for the r a r e - e a r t h element and Y enrich­ ments in Kahoolawe rocks. There was one remaining problem. Why did the Kahoolawe basalts ap-

Composition (wt %) of a rare-earth element/Y bearing phosphate grain Ce

Y

Si

Figure 2. Backscattered electron scanning photomicrograph of rare-earth element/Y-bearing phosphate grains (brightest areas) and photos showing distributions of selected elements as determined by X-ray mapping with an electron microprobe. The small white line at bottom right of each photo is a 10-μιη scale bar.

642 A · ANALYTICAL CHEMISTRY, VOL. 64, NO. 11, JUNE 1, 1992

P2Os FeO CaO La 2 0 3 Ce 2 0 3 Pr 2 0 3 Nd 2 0 3 Sm 2 0 3 EuO Gd 2 0 3 Tb 2 0 3 Dy 2 0 3 Er 2 0 3 Yb 2 0 3 Y203 H 2 0, F, CI

32.4 0.75 0.93 5.9 16.7 3.4 14.8 4.3 1.5 3.4 0.28 2.4 0.92 0.92 8.4 ND

Total

97.0

Analysis by electron microprobe; ND indicates not determined.

Sample preparation for XRF-AA-ICP-CHEM.

pear fresh yet contain a weathering product previously unknown in Ha­ waiian rocks? While we were ponder­ ing this problem, several p a p e r s about r a r e - e a r t h e l e m e n t a n d Y transport in geologic systems were p u b l i s h e d (4). A d d i t i o n a l l y , we learned of an ongoing study of Aus­ tralian basalts that were also seem­ ingly fresh b u t contained anoma­ lously high rare-earth element and Y contents (5). After considering our analytical d o c u m e n t a t i o n of t h e Kahoolawe rare-earth element/Y-bearing phos­ phate and the results of the more re­ cent studies, we concluded t h a t in­ cipient w e a t h e r i n g of Kahoolawe rocks was one of two different but re­ lated processes responsible for con­ centrating rare-earth elements and Y in the basaltic rocks. The other was soil formation. Kahoolawe volcano had undergone substantial surface weathering and soil development, and rare-earth ele­ ments and Y can be transported to a weathering front and concentrated during soil formation under certain climatic conditions. The r a r e - e a r t h elements and Y adhere to clays pro­ duced in rocks during the earliest breakdown of primary material, such as groundmass glass, and form sec­ ondary phases such as rhabdophane. Also, because r a r e - e a r t h elements are mobile in aqueous systems, and because rare-earth element solubil­ ity is very sensitive to pH, there are opportunities during surficial alter­ ation for them to fractionate. In addition, Ce solubility is sensi­ tive to oxidation potential, which can lead to a range of Ce anomalies in geologic material. Apparently, small a m o u n t s of w e a t h e r i n g - p r o d u c e d clay minerals in otherwise fresh-

e, Cho dr

10 b i

Q.

io3i

Ε CO

10 4 ΐ

Rare-earth element phosphate __

Mnct lawa

m2

5758 60 62 63 65 Atomic number

The National Science Foundation helped fund this work through g r a n t EAR-8903704. We thank the personnel of the U.S. Navy's Pacific Third Fleet, Pearl Harbor, for their cooperation.

References

(1) Frey, F. Α.; Roden, M. F. In Mantle Metasomatism; Menzies, M.; Hawkesworth, C, Eds.; Academic Press: Lon­ don, 1987; pp. 423-63. (2) Fodor, R. V.; Frey, F. Α.; Bauer, G. R.; Clague, D. A. Contrib. Mineral. Petrol., in press. (3) Roden, M. F.; Frey, F. Α.; Clague, D. A. Earth Planet. Sci. Lett. 1984, 69, 141-58. (4) a. Lottermoser, B. G. Lithos 1990, 24, 151-67. b. Ponader, C. W.; Brown, G. E. Geochim. Cosmochim. Acta 1989, 53, 2893-2903. c. Wood, S.A. Chem. Geol. 1990, 82, 159-86. (5) Price, R. C ; Gray, C. M.; Wilson, R. E.; Frey, F. Α.; Taylor, S. R. Chem. Geol. 1991, 93, 245-65.

PEAK

QUALITY with

Claisse Fluxes (Borates and Phosphates) Get a new perspective on analysis and better results. The CLAISSE FLUXES have exceptional qualities due to their PURITY and COARSE texture. Claisse Fluxes are Tip-Top. FEATURES • free-flowing crystals • low surface area • high density • fused, not mixed • popular and special compositions CONSEQUENT ADVANTAGES • no loss from static electricity • no loss by splattering or foaming on heating very low water absorption • no uncertainty on quantity weighed • no segregation in containers • FREE SAMPLE upon request

R. V. Fodor received a Ph.D. in geology from the University of New Mexico in 1972. He is a professor ofgeology studying the geochemical and mineralogical com­ positions of igneous rocks.

m e

looking Kahoolawe rocks have served as sinks for r a r e - e a r t h elements and Y mobilized during soil formation over the past million years. Although our study explains the o c c u r r e n c e of a n o m a l o u s l y h i g h t r a c e - e l e m e n t c o n c e n t r a t i o n s in some Hawaiian basalts, it does not explain the apparent absence of rareearth element and Y enrichment in the lavas of the main body of the vol­ cano. We can only speculate t h a t eruptions of shield lavas were too rapid to allow weathering and soil formation to occur to the extent of mobilizing r a r e - e a r t h elements and Y. We will continue our efforts to characterize and compare the rareearth element/Y-bearing phases in Kahoolawe lavas and the phases that must be present in the other reported r a r e - e a r t h element/Y-enriched Ha­ waiian rocks, such as on Oahu. This marks a departure from traditional studies of Hawaiian geochemistry, but it will increase our understand­ ing of r a r e - e a r t h element mobility and phases in geologic systems.

7071

Figure 3. Rare-earth element pattern for the composition of the phosphate in the groundmass of Kahoolawe lavas, compared with the pattern for a lava that contains it (host lava).

Gabor Dobosi received a Ph.D. in geology from Kossuth Lojos University, Hungary, in 1980. He is a research geologist spe­ cializing in microprobe analyses of min­ eral phases in basalt and peridotite rocks. G. R. Bauer received an M.S. degree from the University ofHawaii in 1970. He was trained as a petrologist studying igneous rocks and L· now a specialist in ground­ water geology.

For world-wide sales, address of local agents and service information please call or write to:

corporation scientifique claisse inc.

2522, chemin Sainîe-Foy Sainte-Foy (Québec) Canada G1V 1T5 Tel: (418) 656-6453 Fax:(418)656-1169 Telex: 051-31731

The First and Finest in Fusion. CIRCLE 22 ON READER SERVICE CARD

ANALYTICAL CHEMISTRY, VOL. 64, NO. 11, JUNE 1, 1992 · 643 A