Physico-chemical properties and toxicological effects on plant and algal models of carbon nanosheets from a nettle fibre clone

Syed Shaheen Shah,Roberto Berni,Irshad Ahmad,Servane Contal,Jean-Francois Hausman,Giampiero Cai,Cecilia Del Casino,Khawar Sohail Siddiqui,Sébastien Cambier,Gea Guerriero,Mohammed Ameen Ahmed Qasem,Stefano Predieri,Md.Abdul Aziz,Edoardo Gatti

doi:10.1038/s41598-021-86426-5

Abstract

Carbon nanosheets are two-dimensional nanostructured materials that have applications as energy storage devices, electrochemical sensors, sample supports, filtration membranes, thanks to their high porosity and surface area. Here, for the first time, carbon nanosheets have been prepared from the stems and leaves of a nettle fibre clone, by using a cheap and straight-forward procedure that can be easily scaled up. The nanomaterial shows interesting physical parameters, namely interconnectivity of pores, graphitization, surface area and pore width. These characteristics are similar to those described for the nanomaterials obtained from other fibre crops. However, the advantage of nettle over other plants is its fast growth and easy propagation of homogeneous material using stem cuttings. This last aspect guarantees homogeneity of the starting raw material, a feature that is sought-after to get a nanomaterial with homogeneous and reproducible properties. To evaluate the potential toxic effects if released in the environment, an assessment of the impact on plant reproduction performance and microalgal growth has been carried out by using tobacco pollen cells and the green microalga Pseudokirchneriella subcapitata. No inhibitory effects on pollen germination are recorded, while algal growth inhibition is observed at higher concentrations of leaf carbon nanosheets with lower graphitization degree.

Highlights

Carbon nanosheets are two-dimensional nanostructured materials that have applications as energy storage devices, electrochemical sensors, sample supports, filtration membranes, thanks to their high porosity and surface area
This biopolymer is composed for approximately 44% of C; the C content can increase to around 80% with pyrolysis at high temperatures and reach 95% using various activating a gents[23,24]
The preparation of highly porous activated CNS from nettle tissues with interesting properties in terms of porosity and active surface area was demonstrated in the present study by using pyrolysis at 650 °C

Summary

Introduction

Carbon nanosheets are two-dimensional nanostructured materials that have applications as energy storage devices, electrochemical sensors, sample supports, filtration membranes, thanks to their high porosity and surface area. The nanomaterial shows interesting physical parameters, namely interconnectivity of pores, graphitization, surface area and pore width. These characteristics are similar to those described for the nanomaterials obtained from other fibre crops. The advantage of nettle over other plants is its fast growth and easy propagation of homogeneous material using stem cuttings. This last aspect guarantees homogeneity of the starting raw material, a feature that is sought-after to get a nanomaterial with homogeneous and reproducible properties. The final characteristics of the C nanomaterials deriving from plant biomass depend on the homogeneity of the biological material. Cultivating clones (instead of varieties) under controlled conditions enables to collect biological material with homogeneous properties

Methods

Results

Conclusion