AUTHOR=Taylor Gillian , Williams Rhys , Halldórsdóttir Hrafnhildur Helga , Carter Ashleigh , Birley Andrew , Meyer Alexander , Orr Caroline Hayley TITLE=Archaeological soil from Roman occupational layers can be differentiated by microbial and chemical signatures JOURNAL=Frontiers in Soil Science VOLUME=3 YEAR=2023 URL=https://www.frontiersin.org/journals/soil-science/articles/10.3389/fsoil.2023.1129040 DOI=10.3389/fsoil.2023.1129040 ISSN=2673-8619 ABSTRACT=Introduction

Soil at the Roman site of Vindolanda (Northumberland, UK) provides excellent preservation of wooden artefacts including Roman writing tablets.

Methods

In this study we examined chemical and microbial signature changes within varied occupation contexts of archaeological soil. Analysis included investigating elemental composition, sterol biomarkers, bacterial diversity and community structures from excavation trenches at Vindolanda using pXRF, GC-MS and 16S rRNA gene amplicon sequencing. Samples were taken from varying depths starting at topsoil and working down through layers of Roman occupation including one cavalry stable floor, two infantry barracks and a cook house, and layers which contained Roman writing tablets.

Results and Discussion

The chemical results indicate that areas where wooden artefacts were found had increased soil moisture which was also correlated with specific chemical conditions including shifts in iron, sulphur and phosphorous concentration. Steroid biomarkers indicate the presence of faecal matter in layers, supporting occupation descriptions. Overall microbial diversity did not change across the depth profile but was correlated with soil moisture. Anaerobic soils associated with more optimal preservation differed to other soils with increases in Firmicutes, Proteobacteria, Campilobacterota and Bacteroidota observed. Microbial community structure and putative function as revealed by PICRUSt2 is linked to occupation usage rather than depth of samples with laminated floor layers differing from turf structures. Understanding the complex processes within archaeological soil can help us to understand dynamics of decomposition and preservation. In addition, the apparent preservation of the environmental microbial community as well as the artefacts themselves allows us to understand the microbial environments of the past, how they relate to the present and what this means for our changing environments in the future.