Characterization of Climate Extremes on Plants and Soil Properties Using Nano-Dynamic Elastomechanic Response Analysis
Received Date: Apr 30, 2015 / Accepted Date: May 29, 2015 / Published Date: Jun 08, 2015
This paper presents a nano dynamic plant response relationship by varying soil moisture content due to climate change. An advance soil condition monitoring technique using Laser Interferometry based biomechanical experiment is presented. Sensitive elasto-mechanic reversible R ΔL=0.0001mm and irreversible ( I ΔL=0.005mm) growth response of plants by multiple external environmental variables at nano level are measured. Such response is mathematically correlated with the mechanics of transpiration and soil physical properties (Dry and Wet) or more precisely water content and finally as a derivative of climate change. These dynamic changes in plant growth demonstrate the nano level effect of climate change is an alarming signature and it has been suggested that precipitation changes may have limited transpiration mechanism causing the lack of irreversible plant growth. It is also suggested that the change in plant diameter can be used to trigger alarming system for monitoring global warming.
Keywords: Mutable response; Reversible growth; Elastomechanics; External stimulant; Nanodynamics
Citation: Das S, Mittal SK (2015) Characterization of Climate Extremes on Plants and Soil Properties Using Nano-Dynamic Elastomechanic Response Analysis. J Earth Sci Clim Change 6: 278. Doi: 10.4172/2157-7617.1000278
Copyright: ©2015 Das S, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
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