People | Locations | Statistics |
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Chatterjee, Abhijit |
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Abdullin, S. |
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Chatterjee, R. M. |
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Tadel, M. |
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Anguiano, J. |
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Polatoz, A. |
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Kiminsu, U. |
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Jofrehei, A. |
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Ambrozas, M. |
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Kwok, K. H. M. |
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Nogima, H. |
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Kaestli, H. C. |
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Bury, F. |
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Wayne, M. |
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Adiguzel, A. |
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Musienko, Y. |
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Hadley, N. J. |
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Mal, Prolay |
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Reichert, Joseph |
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Cooper, S. I. |
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Alves, G. A. |
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Lincoln, D. |
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Hirschauer, J. |
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Koseyan, O. K. |
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Droll, A. |
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Richardson, C.
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (11/11 displayed)
- 2019Search for excited leptons in %5Cell%5Cell%5Cgamma$ final states in proton-proton collisions at %5Csqrt{s}$ =13 TeVcitations
- 2017Search for a heavy composite Majorana neutrino in the final state with two leptons and two quarks at %5Csqrt{s}$ =13 TeVcitations
- 2017Search for Low Mass Vector Resonances Decaying to Quark-Antiquark Pairs in Proton-Proton Collisions at root s=13 TeVcitations
- 2016Search for massive WH resonances decaying into the l%5Cnu b%5Cbar{b}$ final state at %5Csqrt{s}$ =8 TeVcitations
- 2016Search for excited leptons in proton-proton collisions at %5Csqrt{s}$ =8 TeVcitations
- 2016Measuring the embodied carbon content of concrete paving
- 2016Search for excited leptons in proton-proton collisions at root s=8 TeVcitations
- 2016Search for massive WH resonances decaying into the l nu b(b)over-bar final state at root s=8 TeVcitations
- 2015Search for physics beyond the standard model in final states with a lepton and missing transverse energy in proton-proton collisions at root s = 8 TeVcitations
- 2015Search for physics beyond the standard model in final states with a lepton and missing transverse energy in proton-proton collisions %5Csqrt{s}=$ 8 TeVcitations
- 2012The synthesis, structures and reactions of zinc and cobalt metal-organic frameworks incorporating an alkyne-based dicarboxylate linkercitations
Places of action
conferencepaper
Measuring the embodied carbon content of concrete paving
Abstract
This paper summarises the outcomes of a PhD research project by Richardson (2009) to measure the embodied carbon content of concrete paving and to reveal the barriers to its accurate measurement. This is a current area of research due to the concerns arising from the anthropogenic emission of carbon dioxide which has been identified as a key cause of climate change. The work was carried out in co-operation with a major manufacturer of concrete paving revealing the practicalities of energy auditing within an existing factory using its unmodified infrastructure, methods of energy metering and recording. The work involved identifying all of the energy inputs involved in the manufacturing process during a financial year. The auditing boundaries were restricted to the main manufacturing facility and its immediate suppliers of raw materials commonly known as cradle to gate. The energy applicable to the paving material had to be apportioned from site wide energy usage. The energy used to supply the raw materials and operate the manufacturing facility was then converted to an amount of carbon dioxide released using standard conversion factors. The barriers to accurate auditing were identified and an embodied carbon coefficient for the raw materials and finished product determined. The embodied carbon contents that were determined differed from those found in the national database. A number of factors are identified that could have contributed to this and suggestions for further research made.