[in press] Production of Wood Pellets from Wood Waste. Whittaker, C. In: Sustainable greenhouse gas reductions from bioenergy systems. Elsevier.
[in press] Biomass Harvesting, Processing, Storage and Transport. Whittaker, C. & Shield, I. In: Sustainable greenhouse gas reductions from bioenergy systems. Elsevier.
[2017] Factors affecting wood, energy grass and straw pellet durability - A review. Whittaker, C. & Shield, I. Submitted to Sustainable and Renewable Energy Reviews.
[2017] Continuous weighing of a pile of poplar wood chips - A Comparison of methods to determine the dry matter losses during storage. Lenz, H., Pecenka, R., Idler, C., Dumfort, S., Whittaker, C., Ammon, C., Hartung, E. Biomass and Bioenergy.
[2016] Testing the use of static chamber boxes to monitor greenhouse gas emissions from wood chip storage heaps. Whittaker, C., Yates, N. E., Powers, S. J., Donovan, N., Misselbrook, T. & Shield, I. Bioenergy Research.
[2016] Comparative evaluation of GHG emissions from the use of Miscanthus for bio-hydrocarbon production via fast pyrolysis. Shemfe, M. B., Whittaker, C., Gu, S. & Fidalgo, B. Applied Energy. 176 pp. 22-33.
[2016] How well does Miscanthus ensile for use in anaerobic Digestion? Whittaker, C., Hunt, J., Misselbrook, T., & Shield, I. Biomass and Bioenergy. 88 pp. 24-34.
[2016] Dry matter losses and methane emissions during wood chip storage: The impact on full life cycle greenhouse gas savings of short rotation coppice for heat. Whittaker, C., Macalpine, W., Yates, N, E. & Shield, I. Bioenergy Research.
[2016] Dry matter losses and greenhouse gas emissions from outside storage of short rotation coppice willow chip.
Whittaker, C., Yates, N. E., Powers, S., Misselbrook, T. & Shield, I. Bioenergy Research. pp. 1-15.
[2015] Chapter 10: Short Rotation Woody Energy Crop Supply Chains. Whittaker, C. & Shield I. In Biomass Supply Chains for Bioenergy and Biorefining. (Eds Jens Bo Holm-Nielsen and Ehiaze Augustine Ehimen) Elsevier.
[2015] Challenge Clusters Facing LCA in Environmental Decision-Making: What we can learn from biofuels?
McManus, M. C., Taylor, C. M., Mohr, A., Whittaker, C., Scown, C. D., Li-Borrion, A., Glithero, N. J. & Yin, Y. Journal of Life Cycle Assessment. 20 pp. 1399-1414.
[2015] How certain are greenhouse gas reductions from bioenergy? Life cycle assessment and uncertainty analysis of wood pellet-to-electricity supply chains from forest residues. Roeder, M., Whittaker, C. & Thornley, P. Biomass & Bioenergy. 79 pp. 50-63
[2015] Life cycle assessment of biofuels in the European Renewable Energy Directive: a combination of approaches? Whittaker, C. Greenhouse Gas Measurement and Management. 4 pp. 124-138.
[2014] The Renewable Energy Directive and Cereal Residues. Whittaker, C., Li-Borrion, A., Newnes, L. & McManus, M. Applied Energy: 122 pp. 207-215.
[2013] A Comparison of Carbon Accounting Tools for Bioenergy and for Whole Farms. Whittaker, C., McManus, M. & Smith, P. Environmental Software and Modelling: 46 pp. 228-239.
[2012] Securing a Bioenergy Supply: UK and US. Whittaker, C., Adams, P. & McManus, M. In: Perspectives on Biofuels: Potential Benefits and Possible Pitfalls. Vol. 1116. ACS Books, pp. 171-187.
[2011] Greenhouse gas reporting for biofuels: A comparison between the RED, RTFO and PAS2050 methodologies. Whittaker, C., McManus, M. & Hammond, G. Energy Policy: 39 pp. 5950-5960.
[2011] The Life Cycle Analysis of Extracting Forest Residues for Biomass Production. Whittaker, C., Mortimer, N., Murphy, R., & Matthews, R. Biomass & Bioenergy. 35 pp. 4581-4594.
[2011] Life Cycle Assessment and Sustainability Methodologies for Assessing Industrial Crops, Processes and End Products. Black, M., Whittaker, C., Hosseini, S.A., Diaz-Chavez, R., Woods, J., & Murphy, R.J. Industrial Crops and Products. 34 pp. 1332-1339.
[2009] Integrating Spatial Estimates of Yield with Dynamic Soil C Modelling (Roth C), to Predict Emissions from Four Bioenergy Crops in England and Wales. Hiller, J., Whittaker, C., Dailey, G., Aylott, M., Casella, E., Richter, G., Riche, A., Murphy, R., Taylor, G. & Smith, P. Global Change Biology Bioenergy. 1, 267-281.