All Stories

  1. Prediction of upland cotton micronaire accounting for the effects of environment and crop demand from fruit growth

    Article • Crop Science, December 2021, Wiley

    Michael Bange

  2. Effects of elevated temperature and elevated CO2 on soil nitrification and ammonia-oxidizing microbial communities in field-grown crop

    Article • The Science of The Total Environment, July 2019, Elsevier

    Professor Brajesh K Singh, Michael Bange

  3. A new probabilistic forecasting model for canopy temperature with consideration of periodicity and parameter variation

    Article • Agricultural and Forest Meteorology, February 2019, Elsevier

    Michael Bange

  4. Cold plasma treatment for cotton seed germination improvement

    Article • Scientific Reports, September 2018, Springer Science + Business Media

    Dr Anne Mai-Prochnow, Michael Bange

  5. Flooding and prolonged drought have differential legacy impacts on soil nitrogen cycling, microbial communities and plant productivity

    Article • Plant and Soil, August 2018, Springer Science + Business Media

    Professor Brajesh K Singh, Michael Bange

  6. Impacts of waterlogging on soil nitrification and ammonia-oxidizing communities in farming system

    Article • Plant and Soil, March 2018, Springer Science + Business Media

    Professor Brajesh K Singh, Michael Bange

  7. Responses of the soil microbial community to nitrogen fertilizer regimes and historical exposure to extreme weather events: Flooding or prolonged-drought

    Article • Soil Biology and Biochemistry, March 2018, Elsevier

    Professor Brajesh K Singh, Michael Bange

  8. Protecting cotton crops under elevated CO2 from waterlogging by managing ethylene

    Article • Functional Plant Biology, January 2018, CSIRO Publishing

    Michael Bange

  9. Endogenous Ethylene Concentration Is Not a Major Determinant of Fruit Abscission in Heat-Stressed Cotton (Gossypium hirsutum L.)

    Article • Frontiers in Plant Science, September 2017, Frontiers

    Michael Bange

  10. Interactive effects of elevated CO 2 , temperature and extreme weather events on soil nitrogen and cotton productivity indicate increased variability of cotton production under future climate regimes

    Article • Agriculture Ecosystems & Environment, August 2017, Elsevier

    Professor Brajesh K Singh, Michael Bange

  11. Economics and risk of adaptation options in the Australian cotton industry

    Article • Agricultural Systems, January 2017, Elsevier

    Dr Karl Behrendt, Michael Bange

  12. The effect of elevated atmospheric [CO2] and increased temperatures on an older and modern cotton cultivar

    Article • Functional Plant Biology, January 2017, CSIRO Publishing

    Michael Bange

  13. Warming alters the positive impact of elevated CO2 concentration on cotton growth and physiology during soil water deficit

    Article • Functional Plant Biology, January 2017, CSIRO Publishing

    Michael Bange

  14. Effects of a wheat rotation on cotton production in a changing climate: a simulation study

    Article • Climate Research, September 2016, Inter-Research Science Center

    Michael Bange

  15. Effectiveness of agronomic practices in dealing with climate change impacts in the Australian cotton industry — A simulation study

    Article • Agricultural Systems, September 2016, Elsevier

    Michael Bange

  16. Cotton growth and yield dynamics across canopy layers in response to soil waterlogging

    Article • Australian Journal of Crop Science, August 2016, Southern Cross Publishing

    Michael Bange

  17. Environment and cotton fibre quality

    Article • Climatic Change, June 2016, Springer Science + Business Media

    Michael Bange

  18. Cotton crop maturity: A compendium of measures and predictors

    Article • Field Crops Research, May 2016, Elsevier

    Michael Bange

  19. Low Incident Light Combined with Partial Waterlogging Impairs Photosynthesis and Imposes a Yield Penalty in Cotton

    Article • Journal of Agronomy and Crop Science, January 2016, Wiley

    Najeeb Ullah, Michael Bange

  20. Nitrogen fertiliser requirements of high-yielding irrigated transgenic cotton

    Article • Crop and Pasture Science, January 2016, CSIRO Publishing

    Michael Bange

  21. Inducing waterlogging tolerance in cotton via an anti-ethylene agent aminoethoxyvinylglycine application

    Article • Archives of Agronomy and Soil Science, November 2015, Taylor & Francis

    Najeeb Ullah, Michael Bange

  22. The yield potential of cotton (Gossypium hirsutum L.)

    Article • Field Crops Research, October 2015, Elsevier

    Michael Bange

  23. Cotton crop water use and water use efficiency in a changing climate

    Article • Agriculture Ecosystems & Environment, April 2015, Elsevier

    Michael Bange

  24. Aminoethoxyvinylglycine (AVG) ameliorates waterlogging-induced damage in cotton by inhibiting ethylene synthesis and sustaining photosynthetic capacity

    Article • Plant Growth Regulation, February 2015, Springer Science + Business Media

    Najeeb Ullah, Michael Bange

  25. Understanding of the Interactive Effect of Waterlogging and Shade on Cotton (Gossypium hirsutum L.) Growth and Yield

    Article • Procedia Environmental Sciences, January 2015, Elsevier

    Najeeb Ullah, Michael Bange

  26. Consequences of waterlogging in cotton and opportunities for mitigation of yield losses

    Article • AoB Plants, January 2015, Oxford University Press (OUP)

    Najeeb Ullah, Michael Bange

  27. Comparing cotton fiber quality from conventional and round module harvesting methods

    Article • Textile Research Journal, November 2014, SAGE Publications

    Mr Marinus van der Sluijs, Michael Bange

  28. Cotton crop phenology in a new temperature regime

    Article • Ecological Modelling, August 2014, Elsevier

    Michael Bange

  29. Understanding the molecular events underpinning cultivar differences in the physiological performance and heat tolerance of cotton (Gossypium hirsutum)

    Article • Functional Plant Biology, January 2014, CSIRO Publishing

    Michael Bange

  30. Physiological determinants of high yielding ultra-narrow row cotton: Canopy development and radiation use efficiency

    Article • Field Crops Research, July 2013, Elsevier

    Michael Bange

  31. Near-optimal response of instantaneous transpiration efficiency to vapour pressure deficit, temperature and [CO2] in cotton (Gossypium hirsutum L.)

    Article • Agricultural and Forest Meteorology, January 2013, Elsevier

    Michael Bange

  32. An assessment of alternative cotton fibre quality attributes and their relationship with yarn strength

    Article • Crop and Pasture Science, January 2013, CSIRO Publishing

    Michael Bange

  33. Reduction in radiation use efficiency of cotton (Gossypium hirsutum L.) under repeated transient waterlogging in the field

    Article • Field Crops Research, January 2013, Elsevier

    Michael Bange

  34. Impact of harvest aid timing and machine spindle harvesting on neps in upland cotton

    Article • Textile Research Journal, October 2012, SAGE Publications

    Michael Bange

  35. Can planting date and cultivar selection improve resource use efficiency of cotton systems?

    Article • Field Crops Research, October 2012, Elsevier

    Michael Bange

  36. Physiological determinants of high yielding ultra-narrow row cotton: Biomass accumulation and partitioning

    Article • Field Crops Research, August 2012, Elsevier

    Michael Bange

  37. Developing controlled environment screening for high-temperature tolerance in cotton that accurately reflects performance in the field

    Article • Functional Plant Biology, January 2012, CSIRO Publishing

    Michael Bange

  38. Consequences of immature fiber on the processing performance of Upland cotton

    Article • Field Crops Research, April 2011, Elsevier

    Michael Bange

  39. Optimizing Timing of Chemical Harvest Aid Application in Cotton by Predicting Its Influence on Fiber Quality

    Article • Agronomy Journal, March 2011, Wiley

    Michael Bange

  40. Measuring the Maturity of Developing Cotton Fibers using an Automated Polarized Light Microscopy Technique

    Article • Textile Research Journal, September 2009, SAGE Publications

    Michael Bange