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A Transient Printed Soil Decomposition Sensor Based on a Biopolymer Composite Conductor.

Madhur AtreyaStacie DesousaJohn-Baptist KauzyaEvan WilliamsAustin HayesKaran DikshitJenna NielsonAbigail PalmgrenSara KhorchidianShangshi LiuAnupam GopalakrishnanEloise BiharCarson J BrunsRichard BardgettJohn N QuintonJessica DaviesJason C NeffGregory L Whiting
Published in: Advanced science (Weinheim, Baden-Wurttemberg, Germany) (2022)
Soil health is one of the key factors in determining the sustainability of global agricultural systems and the stability of natural ecosystems. Microbial decomposition activity plays an important role in soil health; and gaining spatiotemporal insights into this attribute is critical for understanding soil function as well as for managing soils to ensure agricultural supply, stem biodiversity loss, and mitigate climate change. Here, a novel in situ electronic soil decomposition sensor that relies on the degradation of a printed conductive composite trace utilizing the biopolymer poly(3-hydroxybutyrate-co-3-hydroxyvalerate) as a binder is presented. This material responds selectively to microbially active environments with a continuously varying resistive signal that can be readily instrumented with low-cost electronics to enable wide spatial distribution. In soil, a correlation between sensor response and intensity of microbial decomposition activity is observed and quantified by comparison with respiration rates over 14 days, showing that devices respond predictably to both static conditions and perturbations in general decomposition activity.
Keyphrases
  • climate change
  • low cost
  • heavy metals
  • human health
  • healthcare
  • public health
  • plant growth
  • risk assessment
  • mental health
  • microbial community
  • social media
  • gold nanoparticles
  • tissue engineering