Carbon footprint of road pavement rehabilitation: case study at KM 99.6 to KM 103.0 in Southbound along Sungai Petani Utara to Sungai Petani Selatan section N2, north-south expressway

Several challenges are facing the development of the industrial sector as a response to resource depletion, environment degradation, and climate change. These phenomena result from substantial carbon dioxide (CO₂) emission and increased carbon footprint. The transportation infrastructure sector cons...

Full description

Saved in:
Bibliographic Details
Format: Thesis
Language:English
Subjects:
Online Access:http://dspace.unimap.edu.my:80/xmlui/bitstream/123456789/78789/1/Page%201-24.pdf
http://dspace.unimap.edu.my:80/xmlui/bitstream/123456789/78789/2/Full%20text.pdf
http://dspace.unimap.edu.my:80/xmlui/bitstream/123456789/78789/3/Zainab%20Ali%20Hulail.pdf
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Several challenges are facing the development of the industrial sector as a response to resource depletion, environment degradation, and climate change. These phenomena result from substantial carbon dioxide (CO₂) emission and increased carbon footprint. The transportation infrastructure sector consumes a large amount of energy and draws upon natural resources, and carbon footprint can be used to measure the amount of CO₂ from road, highway, or an overpass exerts on earth. CO₂ emissions comprise 95% of the total greenhouse gas (GHG) emissions. A carbon footprint is made up of two parts. The primary footprint is a measure of direct emissions, and the secondary footprint is a measure of indirect emissions from the entire life cycle of products. This research identifies and determines the amount of total carbon footprints of fuel used by machineries and quantity of materials used in the pavement rehabilitation of the PLUS Malaysia Berhad at highway site from Sungai Petani Utara to Sungai Petani Selatan km 99.60 – km 103.00 in the state of Kedah, Malaysia. The data for the research are collected from relevant site engineers through interviews and daily logbooks containing records of material and machinery used in pavement rehabilitation. This research adopts the life cycle assessment approach for evaluating the impact of carbon emission using the materials and machineries utilized in pavement rehabilitation. Results reveal that carbon footprints from materials come from quarry dust material, which emits the highest CO₂ producing 3247.91 tons of CO₂e, followed by cement, stone aggregate, and bitumen emit 251.15, 130.74, and 0.11 tons of CO₂e respectively. The dense bitumen macadam (DBM) layer emits the highest carbon footprint, accounting for 45% of carbon footprint emissions, followed by the asphaltic concrete wearing course (ACWC) layer, and asphaltic concrete binder course (ACBC) layer at CO₂ 28% and 27% respectively. Milling machinery emits the highest carbon footprint producing 478.14 tons fossil of CO₂e due to the highest engine capacity of 448.8 kW/h followed by the lorry DBM, lorry ACWC, and lorry dump truck at 459.47, 352.50, 314.64 tons fossil of CO₂e, respectively. The highest carbon footprint emissions are also observed from milling work task, accounting for 38% of total carbon emissions followed by the tasks in DBM, ACWC, and ACBC layers at 27%, 21% and 14% of CO₂ emission, respectively. The premix cutter machinery emits the lowest carbon footprint emission producing 2.64 tons fossil of CO₂e because of engine capacity is 9.5 kW/h, which is the lowest among the machineries. In the long run, these data contribute to improve methods for implementing policies that monitor and mitigate GHG emissions. As a contribution, the findings of this research are expected to assist contractors, town planners, academics, and policy makers in this field to lessen the carbon footprints in the road infrastructure system in Malaysia