Petrogenesis and tectonic significance of amphibolites interlayered with metasedimentary gneisses in the Ivrea Zone, Southern Alps, northwest Italy

Tectonophysics,

PETROGENESIS INTERLAYERED

B.V.. Amsterdam

(Received

of Geolqy,

November

in The Netherlands

ALPS, NORTHWEST

D. SILLS and JOHN

Department

- Printed

AND TECTONIC SIGNIFICANCE OF AMPHIBOLITES WITH METASEDIMENTARY GNEISSES IN THE IVREA

ZONE, SOUTHERN

JANE

187

107 (1984) 187-206

Elsevier Science Publishers

ITALY

TARNEY

Uniuersity

of Leicester, Lercester. LEI 7RH (United Kingdom)

7, 1983; revised version accepted

February

27. 1984)

ABSTRACT

Sills, J.D. and Tarney, metasedimentary

J., 1984. Petrogenesis gneisses

and tectonic

in the Ivrea Zone,

significance

Southern

of amphibolites

Alps, Northwest

Italy.

interlayered

with

Tectono&sics,

107:

187-206. Amphibolites formation

occurring

of the lvrea

characteristics

as elongate

Zone

(N-type)

have higher basalts.

and

mid-ocean

distributions

ridge basalts.

metamorphism

showing

appears

elements

basaltic

The tectonic formed

geochemical

deformed

at a (Palaeozoic)

study

of their

to transitional the rare-earth

elements

typical

layers and boudins

or enriched

in loss of SiO, and variable

including

element

occur as layers up to

in incompatible

occur as thinner

(kinzigite) trace

(E-type)

enrichment

elements,

of and

ocean in Na.

have preserved

characteristics.

model which best explains

highly

the metasedimentary

Type 1 amphibolites

depletion

similar

to have resulted

K. Rb, Ba, Sr and locally Ca, the less mobile elements,

extremely

within

A detailed

Type 2 amphibolites

levels of the more incompatible

Although

the primary

boudins

parentage.

shows that they can be divided into two groups.

100 m thick and have trace-element normal

lenses

are all of igneous

semi-pelitic

subduction

the assemblage

metasediments

of slivers of MORB-like is that

of an accretionary

amphibolites

within

sedimentary

wedge

zone.

INTRODUCTION

The occurrence of amphibolite layers within metasedimentary sequences poses problems as to their origin, particularly where the rocks are so deformed that any original intrusive or sedimentary relationships have been totally destroyed. Such is the case with amphibolites occurring within the metasedimentary gneisses of the Ivrea Zone of the Southern Alps in northwest Italy (Mehnart, 1975). This region is of special interest because it is commonly regarded as a section of the deeper crust (Mehnart, 1975; Fountain and Salisbury, 1981) and therefore can provide information on the processes of crustal development. Amphibolites may be derived from basaltic rocks, from calcareous or dolomitic

0040-1951/84/$03.00

0 1984 Elsevier Science Publishers

B.V.

lxx

shales (Leake, and

carbonate

impossible

1964). or develop bands

to produce

to determine

thin

their origin

must be made to geochemical is unlikely

through

layers

exchange

(Orville,

Although

and significant

occurred, Leake (1964) has shown that primary cal trends may be preserved, thus permitting para-amphibolites.

between

adjacent

1969). In many

from field or textural

techniques.

to have been isochemical

chemical

observations.

metamorphism compositional

pelite

cases it is so recourse

of amphibolites change

may have

magmatic or sedimentary geochemidiscrimination between ortho- and

If the amphibolites have a basaltic protolith. it is vital to assess the extent of low-temperature alteration which is known to have a major effect on the composition (e.g.. Hart, 1970; Cann, 1969). However, several studies have shown that some high field-strength elements (Ti. Zr, Nb, Y) remain relatively immobile during metamorphism and may be used to indicate the original basalt type and possible tectonic setting (Pearce and Cann. 1973: Floyd and Winchester, 1975: Stephenson and Hensel, 1982). This study investigates the geochemistry of the amphibolites and considers their origin and likely tectonic setting which may bear upon the evolution of the Ivrea Zone as a whole. GEOLOGICAL

SE’MING

The Ivrea Zone (Fig.

1) consists

of a steeply

dipping

series of metabasites

and

metasedimentary gneisses of Palaeozoic age inferred by many authors to be a deformed section through the lower continental crust (e.g. Mehnart. 1975). The metasediments (termed “kinzigite” at amphibolite facies and “stronalite” at granu-

Fig. 1. A. Sketch map of the Ivrea Zone. 1980.) Crosses amphibolites: layered

B. Sketch map of Val Strona and Val d’ossola. (After Zingg. IV28. 29, 30, 200, 201. 386. 390, 391 and 391A are type 1 IV21 and 193 are related to the IV25. 26, 32, 199. 378. 379 and 382 are type 2 amphibolites: mark sample localities.

complex.

Samples

189

lite facies) are a heterogeneous Metamorphosed

mafic

mixture

rocks make

of pelite, semi-pelite

up a significant

and carbonate

proportion

rocks.

of the Ivrea Zone

(Fig. 1) and are of two kinds: (a) a large

layered

mafic-ultramafic

Finer0 (Rivalenti et al., 1975) and (b) layers of amphibolite within

complex,

the metasediments.

occurring

in Val Sesia and

It is the amphibolites

at

which

form the subject of this paper, representatives of which are best exposed in Val Strona (Fig. 1). The metamorphic grade increases from amphibolite facies in the southeast to granulite facies in the northwest (Mehnart, 1975; Schmid and Wood, 1976; Hunziker and Zingg, 1980) and the prograde petrological changes in the metabasites have been described in detail by Reinsch (1973a,b); Mehnart (1975) and Zingg (1980). The mafic rocks investigated in this study are of three types: (a) Units of amphibolite, up to 100 m thick but commonly lo-20 m thick, interbanded with garnet-biotite gneiss occurring between Forno and Sambughetto in Val Strona and at Nibbio in Val d’Ossola (Fig. 1). These will be referred to as type 1 amphibolites. (b) Thin layers or lenses, 25-100 cm thick, complexly interfolded with the sediments. These are common in the amphibolite facies zones but also occur in the granulite

facies zones. These wiI1 be referred

to as type 2 amphibolites.

(c) Garnetiferous metabasites occurring at the base of the section at Campello Monti. These are continuous with the pyroxenites and metagabbros of Val Sesia (Capedri et al., 1977) but have a quite different composition from the other metabasites in Val Strona (Dostal and Capedri, 1979). The assumption that all the metabasites in the Ivrea Zone have a common origin (Mehnart, 1975: Zingg, 1980) is not necessarily correct. This paper concentrates on the bulk rock major and trace element chemistry of these

different

metabasic

rocks,

petrography, mineral chemistry elsewhere (e.g., Zingg, 1980).

and

is prefaced

and metamorphism,

by only

limited

discussion

of

as these have been described

In marked contrast to the gabbros from the layered complex, the amphibolites are medium- to fine-grained, well foliated rocks containing alternating felsic and mafic bands.

The amphibolites

in the lower part of Val Strona

comprise

50-70s

green

prismatic hornblende, 20-40% polygonal plagioclase, up to 10% biotite with accessory quartz, apatite and sphene (which usually rims ilmenite). As described by Reinsch (1973a), the colour of the hornblende changes systematically from green to brown as the metamorphic grade increases. The type 1 amphibolites contain up to 30 vol% of a pale green to colourless anhedral clinopyroxene. This has very low TiO,, AI,O,, (< 1.5 wt.%) and Cr,O, contents and has the approximate composition Ca 48-soMg83-.t6Fe15-,6. The clinopyroxene-bearing rocks are banded with pale

190

cl~nopyroxene-plag~~lase

and

darker

hornblende-rich

layers.

Accessory

minerals

include seapolite, sphene. opaque oxides, apatite, green biotite and carbonate. At Nibbio there are 10 cm long pegmatoid lenses containing scapolite

(Me,, ). plagioclase.

(andradite

54%. grossular

Near

Forno

sphene

and

unusual

apricot-coloured

garnet

1 wt.% TiO, ).

33%. with about

in Val Strona.

an

traces of epidate,

a 1 m wide ultramafic

layer consisting

of brown

hornblende, orthopyroxene and olivine occurs. Mafic granulite layers have a polygonal eyuigranular texture consisting of plagioclase, orthopyroxene. clinopyroxene and brown

hornblende

granulites

with accessory

at Campello

Monti

red biotite.

opaque

are garnetiferous

oxides and apatite.

and

pyroxene and plagiociase up to 0.5--l cm across 1 cm across but up to 2.5 cm across.

much

and

coarser

euhedral

The mafic

grained,

garnets

with

generally

0.5

CHEMISTRY

AND PETROGENESIS

Analyses were performed using a Philips PW1400 X-ray fluorescence spectrometer at the University of Leicester following analytical techniques outlined by Tarney et al. (1979a), Marsh et al. (1980) and Weaver et al. (1983). Briefly, major elements were determined on glass discs fused with a lithium tetraborate flux. and trace elements on pressed powder pellets. Major elements, Ni, Zr. Y, Zn, Sr, Rb and Ga were analysed using a rhodiun~ target and Cr. Ti, V, Ba, La, Ce and Nd using a

TABLE Analyses

1

(ppm) of Whin Sill. an Open

amphibolites.

1X1.

University “ill house” standard -I_lV147 -.-~ INAA

Whin Sill

Elem.

run

wth

the Val Strona

IV26. IV28 and IV201 *

fCP(7)

ICP(2)

~.--_ll_____-La

meaa.

recom.

25.0

25.0

19.8

19.8

21.3

<‘c

58.0

57.6

47.5

42.3

44.7

Nd

il.6

72.3

31.1

‘7.3

24.7

Sm

7.3

7.2

4.5

4.7

4.4

ELI

2.26

2.19

4.1

3.4

3.7

Cd

6.X

7.0

4.6

i.8

4.4

‘l-h

1.12

1.0x

0.5.:

Tm Yh

0.45 1.52

0.42 2.4x

0.64

0.6X

(1.74

1.11

0.38

0.37

0.08

0.11

0.14

* The recommended

value is an average of repeated

and JCP (twice) IO show the comparability analyses

is about

5%. for La. 10% for Cr.

analyses.

> 25% for Gd and Tm. For the ICP method

the analytical

the chemical

introduces

separation

technique

probably

IV147 is a sample analysed

hy both INAA

of the two techniques. The analytical precision for the lNAA < 5% for Sm. ELI. Tb and Yb, about 15% for Lu and Nd and precision

further

is I-6% (Walsh et al., 1981) although

errors.

191

TABLE

2

Type 1 amphibolites. Components

Val Strona and Val d’Ossola

Rock samples: IV28

IV28

IV30

IV200

IV201

46.6

47.3

48.4

IV380

IV386

IV390

46.0

46.3

IV391

IV391A

(wt.%)

Chemical ana!vses

47.8 1.92

0.95

1.45

1.97

48.8 1.89

TiO’ SiO

47.1 1.32

Al z;,

17.3

17.0

16.1

16.2

14.7

14.6

Fe203

0.98 16.8

1.72

47.3 1.79

45.9 1.78

13.4

13.9

14.0

11.12

14.35

10.34

10.54

13.76

13.35

9.64

13.33

13.50

13.88

MnO

0.18

0.22

0.18

0.16

0.22

0.21

0.16

0.27

0.19

0.23

MgO

7.06

6.19

11.02

7.28

5.90

6.34

7.76

5.82

6.68

6.17

CaO

13.29

9.22

13.64

14.78

11.60

11.47

16.50

16.27

12.18

15.43

NazO

2.22

3.47

0.99

2.18

2.62

2.31

1.64

2.63

3.35

2.46

K2O

0.86

0.63

0.86

0.72

0.74

0.67

0.63

0.35

0.92

0.44

p205

0.08

0.17

0.06

0.11

0.17

0.17

0.10

0.15

0.15

0.19

100.53

100.97

100.74

100.72

100.08

99.81

100.21

100.24

99.96

100.48

0.69

0.93

1.25

0.52

0.36

0.41

0.74

1.43

0.75

0.79

Total LO1 %

58.8

49.3

70.6

60.8

49.1

51.7

64.4

49.6

52.7

50.0

51

Trace elements @pm) Ni

96

63

299

153

68

70

226

45

50

Cr

298

276

494

345

199

223

598

90

87

96

V

263

352

164

242

663

374

185

321

348

318

Zn

106

129

86

84

116

117

77

93

108

108

Ga

17

23

15

18

20

18

14

19

18

20

Rb

21

7

17

11

6

7

11

4

11

3

Sr

108

157

189

177

125

122

137

171

96

127

Y

30

55

23

30

44

43

25

42

41

48

Zr

72

98

65

102

118

115

59

107

106

118

Nb

3

6

3

4

6

3

2

3

3

3

Ba

57

39

105

48

38

60

46

34

40

38

-cl

3

5.3

4

3.8

3

4.0

4

Ce

8.5

20

7

9

14.9

9

7.7

11

10.8

11

Nd

9.3

17

5

10

14.4

9

6.0

9

8.3

9

Sm

3.4

La

EU Gd Tb

5

<3

1.3 nd

4.8

2.4

1.6

0.8

1.2

3.0

4.8

3.3

4.8

nd

3.3

0.8

1.25

Yb

3.26

4.7

2.0

3.0

LU

0.5

0.71

0.33

0.49

DY

CIP W norms (wt.%) QZ

0

0

0

0

0

0

0

0

0

0

OR

5.1

3.7

5.0

4.2

4.4

4.0

3.7

2.1

5.4

2.6

AB

13.7

27.4

8.3

11.0

22.1

19.6

3.7

7.7

15.9

8.6

AN

34.5

28.7

36.7

32.1

26.1

27.5

36.5

23.7

20.2

25.7

Kc,ck wlple\: 11’2X N F.

I)1

IV200

IV28

2.7

0.0

3.0

71.1

12.9

32.7

IV380

IV.201 0

I\‘?‘11

IV?L)IA

5.5

(> 7

36.3

32.5

40.x

iI

0

0

7.5

‘.I

I\.‘?Y(l

I V?Xh

(3.6

H\i

0

0

0

4.:

13.4

OI-

13.4

1x.7

IN?

0.x

4.5

9.7

1141

S.?

M-l-

2.0

2.6

I .9

7.1

7.4

I7

14

2.5

ILM’I

2.5

3.6

7.7

17

.J.h

I.‘)

i.4

3.4

Ap

0.2

0.4

0.3

0.3

0.4

0.2

(I.4

(I.4

(1

tungsten target. Additional rare earth data were obtained for four samples (IV21, IV26, IV28 and IV201) by instrumental neutron activation analysis at the Open University

using

the method

IV386 and IV391)

of Potts et al. (1981) and

by inductively

London

using

(IV147).

analysed

techniques

Analyses

of type 1 amphibolites

using

coupled

described both

lites as well as metagabbros

by

techniques,

plasma Walsh

for three samples

spectrometry et al. (1981).

(IV378.

at Kings The

gives very comparable

College,

same

results

sample

(Table

1).

are given in Table 2 and those of type 2 amphibo-

from C’ampello Monti

are given in Table

3.

Nature of purent rocks

Chemical analyses istry the amphibolites

(Tables 2 and 3) show that, from their major element resemble aikalineeolivine basaits or olivine tholeiites;

chemabout

c Sphene

OPX

CPX

Fig. 2. ACF diagram for Val Strona amphibolites.

Field of basalts taken from Orvllie (1969).

this and subsequent figures are as follows:

+ = type 1 amphibolites.

of the most incompatible

amphibolites

element-enriched

x

=

from Sambughetto

type 2 amphibolites. (IV32.

IV378.

Symbols on l = three

IV379).

193

Fig. 3. Niggli 100 mg-c-(al-a/k)

half the samples rarely

quartz

plot within

and c-100

being

nepheline

normative.

mg diagrams

normative,

after Leake (1964). Symbols

the remainder

but with a spread

towards

However, a broad similarity with basaltic compositions origin as any rock consisting dominantly of hornblende its origin, will have a similar Chemical

trends

hypersthene

An ACF plot (Fig. 2) shows that the majority

the field of basalt,

para-amphibolites

being

as in Fig. 2

provide (Leake,

major element

compositions.

does not prove an igneous with plagioclase, whatever

chemistry.

the best means 1964). Figure

Ca-rich

or

of samples

of discriminating

3 shows

that

between

the Niggli

c-mg

ortho-

and

and

100

mg-c-( al-alk ) trends for all the amphibolites broadly follow an igneous rather than a sedimentary trend but there is a spread towards Ca-rich compositions for the clinopyroxene-bearing

type 1 amphibolites,

which does not eliminate

origin for some of this group. The type 2 amphibolites

a sedimentary

follow the igneous

trend more

closely. Ni

Cr

A

10

,40

50

80

70

Fig. 4. Cr vs mg and Ni vs rng (100 Mg/(Mg+ pelites is from Leake (1964).

1 t

,40

50

Fe2+ )) for amphibolites.

80

70

Symbols

as in Fig. 2. Field of

81

123

310

12s

24

Ni

Cr

V

Zn

Ga

Trace elemenrs lppm)

50.1

0.71

LO1

mg

100.37

Total

19

93

277

271

100

59.0

0.45

100.45

0.11

0.57

p205

2.82

10.44

0.42

11.26

CaO

7.60

3.26

4.47

MgO

0.16

11.90

0.68

0.19

MnO

K,O

14.17

Fe@.?

16.9

1.40

48.7

IV376

_

Na,O

14.5

3.37

45.9

AI 1%

TiO,

SO,

Chemica! anu~vsbs (wt.4 )

IV32

Rock samples:

of type 2 amphibolites

3

Components

Analyses

TABLE

21

91

21

248

X8

210

87

56.3

0.88

99.64

0.40

0.90

252

1x4

81

53.6

0.88

100.01

0.45

1.22

4.01

9.00

9.35

4.27

6.20

0.15

10.82

16.0

2.36

49.8

lV379

5.23

0.13

10.18

16.7

2.48

50.0

IV378

9

105

144

1976

1076

79.0

2.68

100.04

0.10

0.20

0.80

7.82

23.98

0.17

14.36

5.9

1.11

45.8

IV382

together with two samples (IV21

15

79

253

684

354

70.6

0.45

17

96

206

509

237

64.7

0.34

101.87

0.22

0.13 100.46

0.74

2.51

13.94

9.06

0.14

11.10

13.8

1.86

47.5

IV199

.71.

85

263

427

76

63.6

0.97

100.59

0.26

0.77

1.13

11.48

7.74

0.17

11.22

17.1

1.95

47.8

IV25

of metagabbroa

0.59

2.05

8.92

13.54

0.17

12.71

15.7

1.05

45.6

IV362

and IV193)

19

156

25x

490

323

67.1

0.47

100.70

0.25

0.87

1.56

9.72

8.71

0.22

13.07

14.1

1.98

47.1

IV26

Monti

25

160

429

39

35

49.3

0.89

99.75

0.40

0.79

1.11

11.69

6.30

0.24

14.60

15.4

2.62

46.6

IV3I6

from Campello

24

118

333

146

85

53.1

0.86

99.67

0.36

1.48

1.88

9.52

7.17

0.20

14.24

15.3

2.82

46.7

IV330

21

119

392

103

56

50.5

0.66

100.11

0.27

1.24

1.42

9.52

6.45

0.23

14.21

14.7

2.27

49.8

IV331

149

932

45

14

55.6

1.6.7

101.0

0.02

0.07

1.79

12.37

7.74

0.18

13.90

19.8

I .0x

44.1

IV21

1I’19;

5

21

7.7

Gd

0

13.2

2.5

6.4

1.3

HY

OL

MT

ILM

AP

3.7

24.2

DI

22.8

AN

NE

20.7

AB

0.3

2.6

2.1

13.7

6.6

15.4

0

32.1

23.8

2.5

1.1

4.7

1.8

10.7

0

17.0

2.7

22.8

31.2

7.2

0

0

4.0

OR

LU

CIPWnorms (wt.%) QZ 0

3.5

0.5

Yb

6.5

DY

Tb

2.2

26.4

49.7

25.4

545

6.6

10

13

37

249

EU

39

Nd

7

80

32

367

Sm

36

80

La

Ba

Ce

56

196

Nb

73

21

32

265

Y

Zr

8

246

8

936

Rb

Sr

20

0.9

4.5

1.9

13.8

0

15.8

0.3

23.1

33.5

5.3

0

24

45

18

280

20

239

38

397

1

0.2

2.1

2.5

34.7

20.4

18.5

0

11.9

6.8

1.2

0

10

17

7

21

7

71

11

146

16

0.3

2.0

2.3

31.8

0.9

9.3

0

31.7

17.3

3.5

0

12

20

8

65

7

62

28

62

3

0.5

3.5

2.0

12.7

0

35.1

4.7

24.0

12.3

4.3

0

14

21

7

70

9

96

25

236

13

0.6

3.7

2.0

1.9

24.8

12.9

0

39.1

9.5

4.5

0

16

29

9

110

13

98

30

263

11

0.6

3.7

2.3

15.7

15.4

14.3

0

28.7

13.1

5.1

0

0.4

2.6

0.96

1.65

5.3

21.4

31.5

12.4

56

14

114

28

163

16

0.4

5.0

2.6

0

23.1

17.2

0

34.8

9.4

4.7

1.0

26

50

18

173

21

204

37

199

62

0.2

5.4

2.6

9.3

13.7

13.3

0

29.0

16.0

8.8

0

31

58

22

214

33

190

30

382

49

0.4

4.3

2.6

0

25.6

12.8

0

30.0

12.0

7.3

3.6

20

33

13

198

14

145

40

186

1

0.4

2.0

2.0

22.0

0

12.7

1.3

45.3

12.6

0.4

0

0.25

1.75

0.6

0.9

2.6

6.9

7.0

<3

49

1

32

19

301

3

7

0.6

0

7

0.4

2.1

2.1

20.0

4.3

11.7

0

46.0

12.0

<3

58

1

29

16

352

In view of the significant IOU grade

il~~t~nl~~h~~n~

trencfs. especially

for thttsr elements

that Ni and Cr correlate suites. It ia not possible pelite and carbonate. the trends element

changes of lwsalt.

atnphibolites probably

to produce although

immobile

modified

high

unmodified.

tr;rcc element

uhich

tmmohilc.

Figure 4 &owh

together

protoliths. and

although

samples

analysed

appearance

have igneous

the IcJL~-~(: part ot

basaltic

111’other trace

rock\ suggests that all these

their major

element

or meta~nmatism.

chemistry

Hone~er.

has

relati\,el\.

rare-earth samples

formed from ~~~tas~dirnent~~r~ precursors of similar

to produce

with the close matching

h> metamorphism

field-strength

for igneoub

this range in Ni and C‘r value:, from mlxturc> of

it would be po\aihle

Some of the Ca-rich

amphibolites

arc rclativclv

etc.. see later) to ccmmon

have igneous

been

I~~~~~~during

to cwkkr

well u ith mg ( IOOhlg,. (Mg 4~ Fe)) ah expected

in Fig. 4. Thib evidence.

ratios (Ti/Zr

in hulk cw~~po.sition ivhloh an it i\ a140 important

element ahundancex appear to he on the plots shown could poa‘;ihl\: have

but. in view of their close association

which must be igneoux, it is inferred

\vith

that all the

parentage.

The mafic granulites from C‘ampello Monti (IV21 and IV193: Table 3) have a distinctly different composition from both the type 1 and type 2 amphibolites and data). It is more closely resemble cumuIates from Val Sesia (Sills. unptiblish~d assumed

that

complex

and will be considered

Before

attempting

protoliths.

reflects

the chemical

affinities

basalt.

in Ca with respect

Figures

to normal

Stephenson and Hensel (1982) for amphibolites Australia. In a total alkalis (Na,O + KzO) versus 1971; Fig. 5a). the amphibolites concentrations

of TiO,.

mafic-uitramafic

of the assumed

to assess the degree to which the present

that of the parent

are enriched

of the Val Sesia layered

no further.

to ascertain

it is first necessary

composition samples

these form an extension

straddle

2 and 3 suggest basal&.

of samples,

that some

a feature

noted

by

from the Wongwibinda belt. SiOz plot (Irving and Baragar.

the tholeiite-alkali

basalt

divide.

Nb and P,O, (Figs. 5c.d) suggest that a tholeiitic

more likely for the majority

basalt

amphibolitr

which implies enrichment

but the parent

i.s

of alkalis during

ln~tarnorphisn~ or low temperature alteration. K,O does not correlate well with other. less mobile incompatible elements, particularly in the type 1 anlphibol~tes. where the high abundance (average 0.7 wt.%) relative to these elements suggests that it has been mobile. Rb and Sr similarly have rather variable concentrations suggesting that they too have been affected, but Ba (Fig. 5b) correlates well with Zr. an at low Ba immobile incompatible element. However, some scatter is apparent contents, suggesting that Ba has been slightly modified, especially in the type 1 amphibolites. The normative plagioclase composition. when compared with the A1,0? content of 13.5-17.0 wt.%. suggests a tholeiitic rather than talc-alkaline parent for all but

197

I

ALKALINE

x

x

-!

/ THOLEIITE

0.

Zr

200

x

46 -

4,8

52 SlOP

5,O

. -

+h+

400

x

200

x

0.

*

. -

x

)l

.

7

.

*x

A 50

a

z&b

Fig. 5. (a) Na,O+

,150

,200

K,O

Ba vs Zr. (c) TiO,

,

Zr

,eJJ

vs SiO,. The alkaline

vs Zr. (d) P,O,

(1975). (e) Y vs Zr. Symbols

,100

,150

and tholeiite

vs Zr, alkaline

,200

,

Zr

fields are from Irving and Baragar

and tholeiite

fields are from Floyd

(1971). (b)

and Winchester

as in Fig. 2.

two Na-rich samples (Irving and Baragar, 1971). These may have suffered secondary enrichment in sodium. A tholeiitic parentage would seem likely for the majority of samples

and the mildly nepheline

normative

nature

of about half the samples

could

result from SiO, depletion. It appears therefore, that the main effects of metamorphism are enrichment in K. Rb and in some cases Na, Ba, Sr and locally Ca, but depletion tion

in SiO,. Low temperature

of Ca through

chlorite.

In many cases calcium

Ca has increased Ca-phase,

the replacement

possibly

hydrous

alteration

of plagioclase

is lost (e.g., Valiance,

in some of these amphibolites; calcite,

of basalt by albite

pyroxenes

by

1974) but Fig. 2 suggests that

presumably

at the time of alteration,

causes redistribuand

the growth

permitted

of a new

redistribution

of

calcium. Trace quantities of calcite are found in one of the Ca-rich samples, IV391A. There are, however, no complementary samples obviously depleted in Ca as described by Stephenson and Hensel (1982). Reported chemical trends resulting from seawater alteration of basalt (e.g., Hart, 1970) and spilitisation (Valiance, 1974) show enrichment in Na, K, Sr, Ba and Rb with loss of Ca and Si which, apart from Ca-depletion, are features shown by the Ivrea Zone samples. Some elements, such as Al, Ti, Zr, Y, and Nb generally remain relatively immobile (Pearce and Cann, 1973; Floyd and Winchester, 1975) except where the degree of alteration is very intensive (Valiance, 1974). As the extent of major element mobility in the Ivrea amphibolites is limited and concentrations of immobile incompatible elements closely match those of unaltered basalts, we can reasonably assume that the concentration of these immobile elements will reflect that of the parent basalt.

As previously alkali

basalt

described,

the amphibol~tes czm be ascribed to either tholeiitic or on the basis of their major element chemistry, hut as the

protoiiths

alkali content

has probably

be placed

on

differences

in trace element

this

(Pearce and Cann,

and

increased

during

it is more

instructive

abundances

1973; Langmuir

metamorphism,

not much reliance

to consider

and ratios between

the well established

basalts of different

et al., 1977; Pearce and Norry.

al., 1979). On the basis of Ti. P. Zr, Nb. Ba. Y and REE contents can be divided into two groups. First the type 1 amphiboiites, Strona

and at Nib&o

elements

(Table

exposed

in Val d’Ossoia

between

Forno

of Ba, are typical

of depleted

Type 2 amphiboiites,

rare-earth oceanic

et

the amphiboiites

and Sambughetto

in Vai of these

from I- 2 wt.%, Zr from 70 - 120 ppm. Nb

< 7 ppm, P,O, from 0.08 to 0.7 wt.%, Y from XI-50 ppm and Ba from 40-100 ‘They all have LREE-depleted

types

1979; Saunders

(Fig. 1). have quite low abundances

2; Fig. 5); TiO, ranging

can

patterns.

ppm.

These values. with the exception

tholeiites.

however, show a much greater range of values with Zr up to

250 ppm, Nb from 7.-33 ppm, TiO? up to 3.4 wt.%, P&I, up to 0.5 wt.% but Y is lower. only ranging up to 40 ppm. Ail samples in this group have LREE-enriched rare-earth

patterns,

One sample,

IV32, has very high Nb (56 ppm)

and

is more

alkaline than any other sample. There is good correlation between pairs of incompatible elements (Fig. 5) and an empirical division between alkaline and tholeiitic basalts

based

on Zr-P,OS

(Floyd

and

samples to have tholeiitic affinities. In Fig. 6, the amphibolites are plotted

(a)

(b)

Winchester.

1975) shows

on a Ti/lOO--Zr-Y

the majority

X 3 diagram

of

iPearce

,

Zr Fig. 6. (a) ‘G/100-22-Y plate basalts.

(b) Zr/Y-Zr

x 3 plot after Pearce

and Cann (1973). OFB-ocean

plot after Pearce and Norry (1979). Symbols

floor basal@,WPB-within as in Fig. 2.

199

and

Cann,

1973) and Zr/Y-Zr

accepted

that even modern

diagram,

the diagrams,

diagram

(Pearce

nonetheless,

provide

Figs. 6a and 6b, the type 1 amphibolites type 2 amphibolites no

tendency

and Norry,

1979). Although

day basalts do not always plot “correctly” some indication cluster

of basalt

in the ocean

type. In both

floor field while the

plot either in the ocean floor or the within plate fields. There is

in any

type

of discriminatory

talc-alkaline field. The type 2 amphibolites, elements, are more intimately

diagram

for samples

to plot

have

Nb

and

TiO,

levels

metasediments

in a

which have enhanced concentrations of incompatible mixed with the metasediments, hence it is necessary to

consider whether these higher levels are primary or the result of chemical with the surrounding metasediments. Many of the type 2 amphibolites, surrounding

it is

on this type of

higher

than

that

of the average

exchange however,

composition

(19 ppm and 1.2 wt.% respectively;

of the

Sills, unpublished

data), suggesting that the concentrations in the amphibolites are primary. In fact Figs. 2 and 3 suggest that it is the type 1 amphibolites which are the most altered. On

the basis

concluded the

type

of these

standard

discrimination

that the type 1 amphibolites 2 amphibolites

represent

diagrams

were depleted more

it can be tentatively

ocean-floor

incompatible

basalts,

whereas

element-enriched

oceanic

basalts and possibly even continental tholeiites. These inferences are further confirmed by examination of various trace element ratios (Table 4). Trace element ratios are more affected

useful

for comparison

by small amounts

of different

of fractionation

basalt

types

than absolute

because

ratios

abundances.

are less

One critical

ratio is Y/Nb which varies markedly between different basalt types (Floyd and Winchester, 1975). As can be seen from Table 4, the type 1 amphibolites, with an average depleted enriched

Y/Nb

ratio of 11.24 + 6.4 (2~) compares

(N-type) (E-type)

with that of a typical

MORB. The type 2 amphibolites are more comparable basalts. The same is true for almost all other element

Atlantic

with more ratios with

TABLE 4 Selected element ratios for the Ivrea Zone amphibolites (data from Tables 2 and 3) and analyses of various basalt types * Av. of

Av. of

Av. of

N-type

T-type

E-type

Alkali

type 1

type 2

378 + 379

MORB

MORB

MORB

basalt

Ba/Zr

0.6

1.0

1.7

Ba/Nb

14.8

8.1

Zr/Nb

25.8

Y/Nb

11.2

-

0.13

0.64

1.71

20.7

4

5.4

7.2

8.3

12.1

30

8.5

4.2

1.8

1.9

11

2.7

0.68

BCR-1

1.7

3.7

10

36

5

9.1

i 1

2.1

Zr/P@,

710

564

574

692

495

533

458

514

Ti/Zr

100

96

60

91

95

60

80

73

* N-type, E-type (enriched) and alkali basalt are taken from Wood et al. (1979a); the T-type (transitional) is from Wood et al. (1979b). data for BCR-1, a continental flood basalt is from Abbey (1980).

the exception

of those involving

been affected

by the metamorphism.

depleted

(N-type)

tholeiites,

MORB.

with more enriched compares

Figure 7 shows selected samples plots (not shown). when normalized can he compared

within

the FAMOUS

From the evidence between

a mid-ocean

to

to island-art:

reasonably

well with

tholeiites. whereas the type 3 dmphibolites c can hr: compared basalta. This wide range in basalt ~(~i~p~~sit~o~ls from Val Stmna

well with the range of composition.\

example

normaiised

for Sr and Nb.

the type 1 amphiholites

ocean-floor

cfepletecl

Similar

show large anomalies

In conclusion,

K. Rb. and Ba, the values for which }~avr pr(,bab]>

available

found in the present

region (Langmuir

day Atlantic,

for

et al.. 1977; Tame\;

et al.. 197%).

from these an~phib~~lites it is not possible

to disting~lish

ridge and back-arc

origin.

The type 1 amphibolites occur within a 2.5 km thick so it seems reasonable to attempt to relate them petrogenetically. Multi-ele-

(a) Tape 1 urnphiholites.

section

ment plots (Fig. 7’1demonstrate their close affinity with MORB in all but thr most lithophile elements. Their REE patterns (Fig. 8) show LREE depletion with Ce,/Yb, anomalies.

ranging from 0.66 to 0.98, and There is a range in REE abundances

they have very slight negative Eu with Ce, ranging from 9 to 17 times 7

Fig. 7. (a) Selected Attantic

N-type

type 1 amphibolites

and (b) selected

MORB (Wood et al., 1979a).

type 2 ampbibolites

normalised

to a typical

201 Type

5

1’ La Ce

1

Nd

f

Amphibolltes

I I

““1

Yb Lu

Sm Eu Gd Tb Dy Type

2

Amphibolltes

3

5u-.--kkLa Ce Pr Nd

Sm Eu Gd Tb Dy

Fig. 8. Chondrite normalised REE plots for representative type 1 and type 2 amphiboIites.

and Yb from

chondrite

the shape

of

the

decreasing

mg (sample

9 to 21 times chondrite

REE

patterns.

This

IV386 having

value of 49.1) and with increasing

in REE

an mg number

content

of a phase which has negligible

most

As shown

k,

in Fig. 4, the marked

change in

correlates

with

of 64.4 while IV201 has an mg

levels of other incompatible

fractionation likely.

but there is no significant

increase

elements.

for these elements, positive

correlation

This implies

olivine being the of Ni with mg

confirms the possibility of olivine fractionation. The negative Eu anomalies, coupled with the low Sr values (Fig. 7) suggests plagioclase has been removed. The relatively constant

ratios of Ti/Zr

(average

loo), Zr/Y

(2.5) and Zr/Nb

(26) suggest all these

elements remained incompatible during fractionation, eliminating clinopyroxene and hornblende as major fractionating phases. These data suggest that the most mg-rich samples,

such as IV386,

either

represent

a primary

liquid,

the remaining

liquids

developing by removal of olivine and possibly plagioclase, or that the most mg-rich samples contained cumulus olivine. As the rocks are completely metamorphosed and no igneous The range plagioclase (b) Type

textures remain, it is impossible to distinguish between these possibilities. of REE and high field strength elements is compatible with olivine and fractionation, which implies fractionation at relatively low pressures. 2 ~mp~ib~~i~es. As previously discussed the type 2 amphibolites appear to

have been less affected by low-temperature alteration but the range in composition is much greater. In view of this wide compositional range and the larger area over

which

the amphibolites

were sampled.

it is not realistic

(XRF data). C’e,,‘Yh,

The tectonic considerable

Of. ‘1Ht. .1MPHIROl.I I1.S

evolution

the origins

of the Ivrea Zone is p<)orly understood.

of the amphiholitts

bearing

to relate them

(Fig. Xt ranges from 3.6 tcl .?.I.

‘I b.C’TONIC‘ SIGNIFIC‘AN(‘1,

regarding

t
to the type 1 ~~t~ipllib~)lit~s have (‘~1, Y.. -- 1

p~trogel~~ti~al~y. All samples. in contrast

on this problem.

with the enclosing

There is no evidence

hence information metasediments

as to the nature

has a of anv

basement upon which a sedimentary sequence may have been deposited. Geophysical data suggest that rocks of mantle density approach the surface under the Ivrea Zone (Berckhemer, 1969). but there is no geophysical evidence for continental basement. The metasedimentt amphibolite zone may of course be allochthonous. It is also possible that the ~nterbandi~lg of ~lrnphib~~~ite and tlletased~ment is ;I primary feature of the processes (of crustal growth that may take place at a continental margin

during

development

of an accretionary

The metasediments are dominantly ranging from 52 to 70 wt.%, (Mehnart.

sedimentary

wedge.

composed of quartz-rich pelite with SO, 1975: Sills, unpublished data) and possibly

representing immature sediments such as greywacke (Mehnart. 1975 ). The atnphibolite-facies metasediments are extremely highly deformed so that all bedding has been completely

transposed

are numerous

and

and no original

have also been

bedding

transposed

features into

remain.

narrow

Small quartz

lenses

parallel

veins to the

foliation. The amphibolites. whatever their origin. have been similarly boudinaged into a series of lenses parallel with the regional foliation. The large Mafia-ultramafi~ complex (Fig. 1) intrudes the metasediments but is itself relatively undeformed. with igneous textures and cumulate structures locally preserved (Rivalenti et al.. 1975). The sediments are also intruded by Hercynian granitoids (Fig, 1). This means that the very intense deformation suffered by the metasediments and intercalated amph~boiites predates the emplacement of the mafic complex and is thus of Hercynian or earlier age. There is still uncertainty as to the age of the sediments and their metamorphism. Hunziker and Zingg (1980) obtained a Rh/Sr isochron of 475 of:20 Ma from 30 to 50 kg samples which they have interpreted as the age of granulite facies metamorphism and suggest sedimentation at 500- 700 Ma. However. zircon ages suggest metamorphism at a younger age. perhaps (K$@, 1974; Pm and Vielzeuf, 1983). although interpretation

as young as 300 Ma is subject to ambigu-

ity. The fate of sediments on the oceanic plate during subduction is of considerable interest. It is known that in some cases, such as the Mariana Island Arc. the sediments may be almost entirely subducted forming little or no accretionary wedge (Rarig and Kay, 1981). Even where there is an additional influx of continental-derived sediments, such as the Middle America Trench (Watkins et al., 1982) or the Japan trench (Von Huene et al., 1980), there may be more sediment subducted than accreted, provided that the continental sedimentation rate is relatively low. However,

203

where the sediment subducting

supply

from the continent

plate so that it approaches

are accreted

the trench

back on to the continental

1980). In southern

margin

Chile a major accretionary

late Palaeozoic-early and is exposed

Mesozoic (Forsythe,

on the trenchward

side of the present

made up of continent but is extremely

planes

dipping

at shallow

angles

towards

Moore

wedge developed

with minor

the

at a low angle and the sediments (cf. Alaska,

derived

deformed

and Allwardt,

in this way during

1982; Bartholomew

wedge is predominantly carbonates,

is higher, the effect is to depress

and Tarney.

Patagonian

Batholith.

greywacke-shale along

the continent.

the

in press). The

components

closely-spaced

All bedding

foliation

is completely

transformed and quartz veins, also transposed within the foliation. are abundant. The rocks are very similar to those in Val Strona. The Franciscan complex of California

(e.g., Ernst,

contains

1975). although

components

of oceanic

sediments. During

the formation

thickness

to consist

of an accretionary

predominantly

pre-existing

continental

ocean

or juxtaposed

crust

tectonic ocean

environment crust

basement.

wedge, it is possible

The accreted peridotitic

without

sediments mantle

quartz

stripped

grade, similarly

intermixed

with

immature

for the whole crustal the necessity

off and incorporated

plate.

the large

talc-alkaline

mafic

affinities

body

into

the accreting

deformation (Ernst, 1975; Karig, 1982). Low-grade and suffer dehydration, which leads to the develop-

veins in the overlying

in Val Sesia,

(Rivalenti

The fact that the amphibohtes MORB

and more enriched

on The

from the subducting

rocks.

Contemporaneous

kaline igneous activity may lie well to the continent side of the accreting Although there are no talc-alkaline volcanics in Val Strona. it is interesting that

of a

may be superimposed

of the overriding

is one where slivers of mafic volcanics

may be continually

of abundant

tectonically

of metasediment

against

wedge and subject to continual metasediments are unde~lated ment

much lower in metamorphic

affinity

which

intrudes

et al., 1975; Bigioggero in VaI Strona

tholeiite

or alkalic

wedge. to note has

et al., 19781979).

appear basaltic

the metasediments,

calc-al-

to represent compositions

both N-type is consistent

with an accretionary wedge model. The floor of most oceans is irregular due to the presence of seamounts, fracture zones and transform faults, many of which are the sites of alkali or enriched type MORB. It is these irreguIarities which are more Iikely to be stripped off and incorporated in an accretionary wedge during subduction. The rock type kinzigite may represent metasediment sive deformation in an accretionary wedge, followed

which has undergone pervaby high-grade post-deforma-

tional metamorphism as temperatures approached the equilibrium geotherm. Stronalite is simply the granulite facies equivalent. In Val Strona, stronahtes occur close to the mafic-ultramafic complex and the granulite facies metamo~hism is probably related to its emplacement (Schmid and Wood, 1976). This is further confirmed by the relatively low pressures of metamorphism of about 6-6.5 kbar (Newton and Haselton, 1981).

‘L‘ONC‘I.USIONS

(1)

Amphibolitrs

Zone

(2) On two

occurring

have igneous

rather

the basis

groups;

type

of their

ocean basalt

(3) The

(4)

occurrence

with

metasedinrentar>

formation

of

the

fvrra

they can he divided

into

prc~tolithx.

and cconpoaition,

with

strong

affinities

to depleted

a more varied composition

equivalent

N-type

MORB

to more enriched

compositions.

range in composition

by olivine

the

sedimentary

1 amphibnlites

and type 2 amphibolites (E-type)

w(thin

than

of the type 1 ~in~phih~~lit~s

suggests

It

fractj~~nat~~n. that this section of the crust was huiit

they are related

and FIagioclase is possible

wedge during

up ah an accretionary

the early to mid-Palaeozoic.

ACKNOWLEDGEMENTS

JDS gratefully acknowledges the receipt of an NERC post-doctoral research fellowship. We would like to thank Phil Potts and Olwen Thorpe at the Open University

for the INAA

We are very grateful

data and Nick Walsh at Kings College

for the assistance

of Giorgio

Rivalenti

for the ICP data.

in the field.

REFERENCES

Abbey,

S.. 1980. Studies

minerals.

Geostand.

Bartholomew,

in “standard Newslett.,

D.S. and Tarney.

samples”

J., in press. Geochemtcal

Andes (45 ’ -46 OS). In: R.S. Harmon Isotopic

Constraints,

Berckhemer.

IL.

Bigioggero, farm,

Central

(Editors),

of magmattsm

Andean

evidence

for

the

composition

of

the

A.. Colombo.

A. and Gregnanin.

A.. 197X-1979.

Alps, Italy. Mem. Inst. Geol. Min. Univ. Padua.

S.. Coradini,

Ivrea-Verbano

of stlicate

rocks

and

rn the southern

Magmatism:

Chemical

and

Ltd., Nantwich.

J.R., 1969. Spilites from the Cartsberg

Capedri.

analysis

lower

crust

and

the

Moho.

8: 97-105.

EL, Boriani.

complex,

Direct

characteristics

and B. Barreiro

Shiva Publications

1969.

Tectonophysics.

for use in the general

4: 163.-190.

A., Fanucci.

ridge. Indian

0.. Garuti.

basic formation

(ltalian

Ocean.

of the Ivrra basic

J. Petrol..

IO: l-19.

G. and Rossi. A.. 1977. The origin of the

G., Rivalenti.

Western

The diorites

33: 71-85.

Alps). Statistical

approach

to the peridotite

problem.

Rend. Cont. Sot. It. Miner. Petrol.. 33: 5833592. Dostal.

J. and Capedri.

Alps. Lithos. Ernst,

W.G..

1975. Introduction.

Hutchinson Floyd,

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