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Monitoring seasonal transpiration drying of loblolly and slash pine with time domain reflectometry

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Abstract

The moisture content (MC) of felled trees has a direct impact on transportation costs and efficiency. Transpirational (or field) drying of fallen trees, to reduce MC and subsequently improve the economics of transport can be employed; however, an understanding of seasonal drying rates is required. Typically load cells have been used to track moisture changes in bundles of logs but where access is limited this approach is impractical. Time-domain reflectometry (TDR) provides an alternative approach and was used to monitor seasonal changes in transpirational drying rates for felled loblolly and slash pine at a Lower Coastal Plain site in Florida and loblolly pine at a Piedmont site in Georgia on a weekly basis for approximately one year. Different transpirational drying rates and minimum MC’s were observed by season. Drying rates observed during summer, fall and spring, at both test locations, indicate that after three weeks an equilibrium (or minimum) MC is achieved. Winter drying is slower, and up to 5 weeks in the field (or even longer) may be required. Post equilibrium felled log moisture content continued to vary during most seasons with rainfall events the most probable cause. TDR provides a viable approach for monitoring transpirational drying and subsequent MC changes in felled trees.

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References

  • Acuna M, Anttila P, Sikanen L, Prinz R, Asikainen A (2012) Predicting and controlling moisture content to optimize forest biomass logistics. Croat J For Eng 33(2):225–238

    Google Scholar 

  • Antony F, Schimleck LR, Daniels RF (2012) Identification of representative sampling heights for specific gravity and moisture content in plantation-grown loblolly pine. Can J For Res 42:574–584

    Article  Google Scholar 

  • Belart F, Leshchinsky B, Sessions J (2017a) Finite element analysis to predict in-forest stored harvest residue moisture content. For Sci 63:362–376

    Article  Google Scholar 

  • Belart F, Sessions J, Leshchinsky B, Murphy G (2017b) Economic implications of moisture content and logging system in forest harvest residue delivery for energy production: a case study. Can J For Res 47(4):458–466

    Article  Google Scholar 

  • Borders BE, Harrison WM (1989) Comparison of slash pine and loblolly pine performance on cutover site-prepared sites in the coastal plain of Georgia and Florida. South J App For 13:204–207

    Article  Google Scholar 

  • Constantz J, Murphy F (1990) Monitoring moisture storage in trees using time domain reflectometry. J Hyd 119:31–42

    Article  Google Scholar 

  • Cutshall JB, Greene WD, Baker SA (2013) Transpirational drying effects on energy and ash content from whole-tree southern pine plantation chipping operations. South J App For 37:133–139

    Article  Google Scholar 

  • Dahlen J, Antony F, Li A, Love-Myers K, Schimleck LR, Schilling E (2015) Automated time-domain reflectometry signal analysis for prediction of loblolly pine and sweetgum moisture content. BioResources 10:4947–4960

    Article  CAS  Google Scholar 

  • Dahlen J, Schimleck L, Schilling E (2020) Modeling and monitoring wood moisture content using time-domain reflectometry. Forests 11:479

    Article  Google Scholar 

  • Gjerdrum P, Salin J-G (2009) Open air drying of Scots pine transmission poles prior to creosote treatment. In: Proc. “Wood science and engineering in the third millennium.” Brasov, Romania, pp 95–102

  • Holbrook NM, Sinclair TR, Burns MJ (1992) Frequency and time-domain dielectric measurements of stem water content in the arborescent palm, Sabal palmetto. J Exp Bot 43:111–119

    Article  Google Scholar 

  • Huggett R, Wear DN, Li R, Coulston J, Liu S (2013) Forest forecasts. In: Wear DN, Greis JG (eds) The Southern Forest Future Project: technical report, US For Serv Southern Research Station, FPL-SRS-178, pp 73–101

  • Irvine J, Grace J (1997) Non-destructive measurement of stem water content by time domain reflectometry using short probes. J Exp Bot 48:813–818

    Article  CAS  Google Scholar 

  • Ledieu J, De Ridder P, De Clerck P, Dautrebande S (1986) A method of measuring soil moisture by time domain reflectometry. J Hyd 88:319–328

    Article  Google Scholar 

  • Megraw R (1985) Wood quality factors in loblolly pine. TAPPI Press, Atlanta

    Google Scholar 

  • Murphy G, Kent T, Kofman PD (2012) Modeling air drying of Sitka spruce (Picea sitchensis) biomass in off-forest storage yards in Ireland. For Prod J 62:443–449

    Google Scholar 

  • Nadler A, Raveh E, Yermiyahu U, Green SR (2003) Evaluation of TDR use to monitor water content in stem of lemon trees and soil and their response to water stress. Soil Sci Soc Am J 67:437–448

    Article  CAS  Google Scholar 

  • Panshin AJ, de Zeeuw C (1980) Textbook of wood technology, 4th edn. McGraw-Hill, New York

    Google Scholar 

  • Patterson DW, Doruska PF (2005) Effect of seasonality on bulk density, moisture content, and specific gravity of loblolly pine tree-length pulpwood logs in Southern Arkansas. For Prod J 55(12):204–208

    Google Scholar 

  • Pettinelli E, Cereti A, Galli A, Bella F (2002) Time domain reflectometry: calibration techniques for accurate measurement of the dielectric properties of various materials. Rev Sci Instrum 73:3553–3562

    Article  CAS  Google Scholar 

  • Raitila J, Heiskanen VP, Routa J, Kolstrom M, Sikanen L (2015) Comparison of moisture prediction models for stacked fuelwood. Bioenerg Res 8:1896–1905

    Article  Google Scholar 

  • Raybon H, Schimleck LR, Love-Myers K, Antony F, Sanders J, Daniels R, Andrews E, Schilling E (2015) Examination of the potential to reduce water application rates in pine wetdecks. Tappi J 14:675–682

    Article  Google Scholar 

  • Raybon H, Schimleck LR, Love-Myers K, Antony F, Sanders J, Daniels R, Andrews E, Schilling E (2016) Examination of the potential to reduce water application rates for hardwood pulplogs stored in wet decks. Tappi J 15:515–522

    Article  Google Scholar 

  • Schimleck L, Love-Myers K, Sanders J, Raybon H, Daniels R, Mahon J, Andrews E, Schilling E (2011) Measuring the moisture content of green wood using time domain reflectometry. For Prod J 61:428–434

    Google Scholar 

  • Schimleck LR, Love-Myers K, Sanders J, Raybon H, Daniels R, Andrews E, Schilling E (2013) Examination of moisture content variation within an operational wetdeck. Tappi J 12:45–50

    Article  CAS  Google Scholar 

  • Shiver BD, Rheney JW, Hitch KL (2000) Loblolly pine outperforms slash pine in southeastern Georgia and northern Florida. South J App For 24:31–36

    Article  Google Scholar 

  • Shmulsky R, Jones PD (2011) Forest products and wood science: an introduction, 6th edn. Wiley, West Sussex

    Book  Google Scholar 

  • Sikanen L, Röser D, Anttila P, Prinz R (2013) Forecasting algorithm for natural drying of energy wood in forest storages. For Energy Obs 27:7

    Google Scholar 

  • Sirois DL, Rawlins CL, Stokes BJ (1991) Evaluation of moisture reduction in small diameter trees after crushing. Bioresour Technol 37:53–60

    Article  Google Scholar 

  • Stokes BJ, Watson WF, Miller DE (1987) Transpirational drying of energywood. In: Proceedings of the international winter meeting of the American Society of Agricultural Engineers, paper 87-1530. American Society of Agricultural Engineers, St. Joseph, 14 p

  • Stokes BJ, McDonald TP, Kelley T (1993) Transpirational drying and costs for transporting woodybiomass–a preliminary review. In: Proc. of IEA/BA Task IX, Aberdeen, 16 p

  • Taras MA (1956) Buying pulpwood by weight as compared with volume measure. US For Serv Southeastern Forest Exp Station, Paper No. 74, 11 p

  • Wear DN, Greis JG (2012) The Southern Forest Futures Project: summary report. US For Serv Southern Research Station, GTR-SRS-168, 54 p

  • White RB, Schimleck LR, Antony F, Daniels RF (2019) Utilization of time domain reflectometry to track temporal changes in standing tree moisture content. Eur J Wood Prod 77:1045–1052

    Article  Google Scholar 

  • Wullschleger S, Hanson P, Todd D (1996) Measuring stem water content in four deciduous hardwoods with a time-domain reflectometer. Tree Physiol 16:809–815

    Article  CAS  Google Scholar 

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Acknowledgements

The authors thank the Wood Quality Consortium for assistance in collecting the P. taeda samples and for sample preparation. The support of Rayonier and the Warnell School of Forestry and Natural Resources is also recognized.

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Authors and Affiliations

  1. Warnell School of Forestry and Natural Resources, University of Georgia, Athens, GA, USA

    R. B. White, F. Antony & R. F. Daniels

  2. Department of Wood Science and Engineering, College of Forestry, Oregon State University, Corvallis, OR, 97331, USA

    Laurence R. Schimleck

  3. Department of Forest Engineering, Resources and Management, College of Forestry, Oregon State University, Corvallis, OR, USA

    F. Belart

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  1. R. B. White
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  2. Laurence R. Schimleck
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  3. F. Antony
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  4. F. Belart
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  5. R. F. Daniels
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Correspondence to Laurence R. Schimleck.

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White, R.B., Schimleck, L.R., Antony, F. et al. Monitoring seasonal transpiration drying of loblolly and slash pine with time domain reflectometry. Eur. J. Wood Prod. 79, 1297–1304 (2021). https://doi.org/10.1007/s00107-021-01688-0

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  • DOI: https://doi.org/10.1007/s00107-021-01688-0

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