SWS Academic Research eLibraryEarth & Planetary Sciences

Scholarly record

THE HORNBLENDE MINERAL IN NEOLITHIC POTS. TECHNOLOGICAL SIGNIFICANCE

Lecturer Anca Luca, Daniela Dimofte

First published: 2017-06-20https://doi.org/10.5593/sgem2017/11/s01.077View metrics

Abstract

Several pots belonging to Neolithic cultures from the Romanian Plain contain crystals of brown hornblende. The brown hornblende is a calcic mineral belonging to the amphibole family, a highly complex series of inosilicates. Interestingly, the clay used as raw material for these Neolithic pots contains green, not brown, hornblende. No neighbouring sands (which could be added as a temper) contain such brown crystals. Therefore, the existence of the brown hornblende can be explained by in situ formation at the expense of the green hornblende during the firing process. We have designed and performed heating experiments to test this hypothesis. Crystals of green hornblende were added to clays similar to those used in the ceramics of the Sultana Culture Gumelni?a. Crystal with sizes ranging 0.1-8 mm were selected to reproduce the crystal size distribution found in the Neolithic ceramics of interest. All crystals have an angle of extinction (c/Ng) varying between 20пїЅ-22пїЅ. Heating was performed in 5 steps, with a temperature range of 500пїЅC-900пїЅC.The main results are: - Up to about 600пїЅC, the green hornblende does not change colour, regardless of its shape or size; - Between 600пїЅC-700пїЅC, at a high rate of heating, the green hornblende remains unchanged. At a slower rate of heating the small crystals become brown entirely while the larger ones change colour only along the border. In the large crystals colour and extinction angle change gradually from the brown border to the green core; - At 800пїЅC regardless of the rate of heating, all crystals are tainted brown. Larger crystals, when heated rapidly develop a slight colour zoning and a gradual change in the extinction angle; - Between 800пїЅC and 900пїЅC, irrespective of size and rate of heating all green hornblende crystals become brown with a c/Ng=0. We interpret our observations as the result of oxy-substitution, i.e. hydrogen removal from the group hydroxyl (OH) group in the crystal structure of hornblende, coupled with an oxidation of the iron present in the crystal (Fe2+ to Fe3+). Our experimental results can be used, along other criteria, to estimate the temperature and burning rate of hornblende-bearing Neolithic pots.

Publication Impact Profile

PlumX
  • Citations
  • CrossRef - Citation Indexes: 1
  • Scopus - Citation Indexes: 3
  • Captures
  • Mendeley - Readers: 1

Publication details

Title
THE HORNBLENDE MINERAL IN NEOLITHIC POTS. TECHNOLOGICAL SIGNIFICANCE
Authors
Lecturer Anca Luca, Daniela Dimofte
Proceedings
SGEM International Multidisciplinary Scientific GeoConference EXPO Proceedings; 17th International Multidisciplinary Scientific GeoConference SGEM2017, Science and Technologies in Geology, Exploration and Mining
Publisher
STEF92 Technology
Year
2017
Pages
613-622
SWS Citekey
Luca20171613622
ISSN
1314-2704
ISBN
978-619-7105-98-8
Language
en
Publication type
Conference Paper
Keywords
References0
0references registered for this publication

Structured references will appear here after the reference import pass. The count is preserved now so the scholarly record is not incomplete.

Citing literature

Number of times cited according to Crossref: 1

View or Download full articleAccess options
Full paper accessChoose SWS login, librarian support, or instant article download.

SWS access login

Login as SWS Scientific Committee

Authors and approved SWS contributors will read and export their own linked papers after identity matching by SWS profile, email and SGEM GlobalID.

For librarian assistance: [email protected]

Purchase Instant Access

48-hour online accessComing soon
Online-only accessComing soon
Download the full article in PDF formatEUR 35
  • Article can be downloaded after successful payment.
  • Article may be used according to SWS library access terms.
  • Article cannot be redistributed.
Get full paper

Back to publication list