The Reduction of CO 2 Emissions by Application of High-Strength Reinforcing Bars to Three Different Structural Systems in South Korea

The architecture, engineering, and construction (AEC) industry consume approximately 23% of the national energy annually, and are considered among the highest energy consuming industries. Recently, several studies have focused on establishing strategies to reduce the emissions of carbon dioxide in the AEC industry by utilisation of low-carbon materials, material reuse, recycling and minimal usage; selection of an optimal structural system and structural optimisation; and optimisation of construction operations. While several studies examined material selection and replacement in concrete, there is a paucity of studies investigating the replacement and implementation of high-strength re-bars to lower the carbon dioxide emissions in buildings. To fill this research gap, the purpose of this study involves calculating the emissions of carbon dioxide by applying high-strength reinforcement bars in three different types of buildings. The input–output analysis method was adopted to compute the emissions of carbon dioxide by using the yield strength and size. This study showed that the application of the high-strength re-bars is beneficial in reducing the input amount of materials, although the quantity of reinforcing bars on the development and splice increased. Furthermore, the application of high-strength deformed bars is also advantageous as a means of carbon dioxide reduction in the studied structural systems. In this study, the CO2 emissions of three different structural systems indicated that implementing SD500 re-bars is the most effective method to reduce carbon dioxide emissions.


Introduction
It is widely recognised that architecture, engineering, and construction (AEC) industry significantly impact the environment.The AEC industry consumes approximately 23% of the national energy per year [1].Additionally, the ratio of energy consumption increases to 40% when the production and transportation of construction materials are considered [2].Given that the AEC industry consumes a vast amount of energy, the emission of greenhouse gases is an inevitable phenomenon in this industry.According to IPCC Report [3], approximately 40% of carbon dioxide is emitted from the AEC industry.To lower the environmental burden and satisfy international agreements (e.g., business-as-usual (BAU), Kyoto Protocol [4], or the Paris Agreement), it necessary to focus on alleviating the anti-environmental impacts in the AEC industry.In keeping with the above-mentioned international approaches towards low-carbon and sustainability, the South Korean Government established a goal of lowering carbon dioxide emissions to a maximum of 50% by 2050 as agreed in the 15th United Nations Framework Convention on Climate Change (UNFCCC).
Recently, several studies researched and established strategies to reduce the embodied carbon of buildings by the utilisation of low-carbon materials, material reuse, recycling and minimal usage, selection of optimal structural system and structural optimisation, and optimisation of construction operations [5][6][7][8][9][10][11][12][13].In conjunction with these strategies in building and construction, various studies examined material selection and replacement in concrete.In addition, there are several advantages when high-strength reinforcing bars are applied to buildings such as simplified connections between re-bars, improved workability, retrenchment of labour cost and so forth.However, the replacement of normal strength reinforcing bars with high-strength re-bars for reduction of CO 2 emissions is relatively rare as a low carbon emission material in reinforced concrete structure and buildings.Hence, the aim of this study involves evaluating the environmental performance of high-strength reinforcing bars and assessing the applicability of high-strength re-bars as a means of reducing CO 2 emissions in the rigid-frame structure, bearing wall system, and flat-plate system.

Literature Review
To reduce the emitted carbon dioxide in the architecture, engineering, and civil industry, it is extremely effective to lower the CO 2 emissions from all materials that consume significant amounts of energy and emit a high proportion of greenhouse gases.There are several stages involved in constructing buildings or structures.Generally, this is divided into four phases: construction, operation and maintenance, decomposition, and demolition.Tae et al. [14] propose a simple CO 2 assessment system over the entire life cycle of apartment housing in South Korea.They divided a building's life cycle into four broad phases, namely a construction stage, an operation stage, a maintenance stage, and a dissolution and disposal stage.According to them, the construction stage is the most energy intensive phase of a building's life cycle, and emits the highest amount of CO 2 .Additionally, they indicate that six major construction materials, including reinforced steel, ready mixed concrete, plywood, concrete product, industrial plastic products, and pain and vanish, account for approximately 80% of carbon dioxide emissions during the construction phase.The suggested simplified method for assessing the life cycle CO 2 of apartment housing shows results that are in agreement with those from the existing approach, with respect to the calculation of the life cycle of CO 2 emissions.Yan et al. [12] suggested a calculation method for GHG emissions in building construction in Hong Kong.They defined the sources of GHG emissions into four sources, namely manufacturing and transporting of buildings materials, energy consumption of construction equipment, energy consumption for processing resources, and disposal of construction waste.In their case study (One Peking in Hong Kong), the main source of CO 2 emissions in building construction involves manufacturing and transporting the materials and energy for equipment operation, which account for approximately 98.6% to 99.2% of CO 2 emissions.The results indicate that the majority of GHG emissions are due to ready-mixed concrete and reinforcement bars.They suggest that the application of recycled materials (especially re-bars) is a crucial method to lower the GHG emissions in building materials.
As reviewed, the most significant phases in terms of CO 2 emissions in the construction industry is the construction phase.Additionally, reducing the CO 2 emissions from the construction stage is the most important factor in the success of carbon reduction of a building.There are several carbon reduction strategies during the construction phase in building construction.Akbarnezhad and Xiao [15] reviewed extant studies in terms of strategies and methods to reduce the embodied carbon of buildings.They suggest that the embodied carbon of construction materials exhibits a relatively increased trend due to the recent advances in minimising the operating emissions of carbon dioxide.They categorise lowering the embodied carbon of buildings into five categories, namely using low-carbon materials, minimal utilisation of materials, recycling of materials, supplying materials to local suppliers, and constructing buildings with optimisation strategies.The most prevalent strategy of lowering the embodied carbon is the application of low-carbon materials in buildings.Cole [16] examines energy consumption and greenhouse gas emissions with the on-site construction of different material applications (i.e., wood, steel, and concrete).The results show that concrete consumes the highest energy as well as emits the highest amount of greenhouse gas.The runner-up for energy consumption and CO 2 emissions is structures with wood.A steel structure is the lowest energy consumer as well as the lowest greenhouse gas emitter.A remarkable aspect of this study is that it reflects the energy consumption of transportation of construction personnel to and from the construction site.The results indicate that the energy consumption of transportation is not insignificant, and it accounts for approximately 5-85% based on the type of construction materials.
An extremely common method to reduce carbon dioxide from buildings involves implementing low-carbon emitting materials or substituting higher components for lower components.González and Navarro [6] indicated that selection of appropriate and low environmental materials in construction significantly impacts the reduction of carbon dioxide emission from construction sites.They maintained that the proper selection of low CO 2 emitting materials lowers the emissions by approximately 28%.According to Cho and Chae [17], lowering the impact of buildings on the environment requires the utilisation of low-carbon emitting materials.They show that buildings with low-carbon materials emit approximately 25% less carbon dioxide emissions when compared with those of the conventional buildings.Additionally, they suggest two methods of producing low-carbon construction materials, namely by using recycled materials or industrial by-products, and by shortening the manufacturing process of the materials.According to their research, the top ranking of carbon dioxide emissions amongst construction materials is ready-mixed concrete.Additionally, they analysed the emissions of CO 2 by phases during the entire life cycle of a building.Cho and Chae [17] indicated that the operation phase is the most energy consuming stage of the whole life cycle of a building, and the construction period is followed by the operation phase.Tae et al. [18] examine the influence of high-strength concrete as a means of low environmental impacts materials in high-rise buildings.A reduction of CO 2 emissions is expected given the replacement of the normal strength concrete by high-strength concrete since the amount of concrete and re-bars were lowered, and the lifespan of the structures were prolonged when compared with those of the buildings to which normal strength materials were applied.When the aspect of structural systems is considered, the application of high-strength concrete leads to a significant reduction in vertical members.The study also points out that relatively more CO 2 is emitted when high-strength concrete is applied although it is possible to reduce CO 2 emission by substituting a portion of cement with industrial wastes or by-products such as blast furnace slag.
Another endeavour to reduce carbon dioxide in the building construction industry involves constructing a building with optimal design.This approach is closely related to the structural design of a building.Baek et al. [19] investigated the relation in CO 2 emissions between different types of building structures.They compared a block type (i.e., bearing wall system) that is commonly used in constructing apartment buildings in South Korea, to a column and beam system.The results indicate that the structural systems have a significant influence on lowering carbon dioxide emissions during the construction stage.Additionally, they also consider CO 2 reductions in terms of material substitution from normal strength concrete to high strength concrete.They insist that, although the total emissions of CO 2 in high strength concrete exceeds those in normal concrete, CO 2 emissions are reduced when blast furnace slag is added, up to 20%.Kim et al. [20] suggest three ways to reduce CO 2 emissions of concrete structures based on building type and regional attributes.They indicate that high-strength concrete is effective in lowering the occurrence of carbon dioxide, since the application of high-strength concrete requires a reduced quantity of reinforcing bars and concrete.The concrete mix design adds an appropriate admixture, such as blast furnace slag, and constitutes a method to reduce CO 2 emissions in concrete structures.Finally, minimising the distance between the ready-mixed concrete plant and the construction site is important with respect to the emissions of carbon dioxide that occur during the transportation of construction materials.However, the proposed methods only assessed CO 2 emissions during the construction stage including raw material, transportation, and manufacturing.Thus, its application is extremely limited for the evaluation of Life Cycle CO 2 (LCCO 2 ) for concrete structures.Additionally, they did not consider other construction materials, such as reinforcing bars, paint, glass, and insulating materials, although the concrete includes significant amount of CO 2 emissions.Moreover, Park et al. [21] propose an optimal design method of steel reinforced concrete in high-rise buildings.They maintain that a main source of emitting carbon dioxide in construction corresponds to construction materials.Thus, the results indicated that this reduces the amount of CO 2 emissions when the structural design considers the CO 2 emission and reflects the results in this phase.In the study, the application of high-strength materials, such as high-strength concrete and steel, is extremely effective in reducing the emissions of carbon dioxide although the initial cost and the unit CO 2 emission exceed those of the normal materials.According to the above-mentioned assertion, the input amount of high-strength materials is a main reason for the reduction in costs and CO 2 emissions.
Nadoushani and Akbarnezhad [22] examined the relationships between different structural systems and carbon footprints of buildings as opposed to the replacement of low-carbon materials.They suggest that relatively little research has focused on the selection of the structural systems to reduce the carbon footprint of buildings.Additionally, they point out that most studies consider the application of low-carbon materials as the consequence of structural design.However, Nadoushani and Akarnezhad [22] suggested that comprehensive assessment of embodied carbon and operating carbon during the structural design is very important for life cycle carbon assessment.For example, steel structures have relatively low embodied carbon, but a high level of operating carbon since the thermal mass is considerably lower than that of concrete structures.In a nutshell, selection of the best structural design alternative to reduce the carbon footprint should be based on the effects of the structural system on the life cycle carbon footprint rather than the carbon footprint of individual life cycle phases.
Reinforcing bars are considered as a main construction material when considering Life Cycle Assessment (LCA), Life Cycle Inventory Database (LCI DB), and LCCO 2 [22][23][24][25].Although reinforcing bars are regarded as a main carbon dioxide emitter in the AEC industry, very few studies examined the reduction in CO 2 emission from the application of re-bars.In South Korea, Choi et al. [23] suggest a new method to calculate the basic unit of CO 2 emission of re-bars by applying an individual integration method.However, this study focuses on new ways to quantify the amount of CO 2 from cradle-to-gate instead of the application of LCCO 2 assessment.Moreover, Han and Kim [24] propose that the application of high-strength materials, such as concrete and reinforcement bars, is an effective way to lower the occurrence of carbon dioxide in reinforced concrete, although they did not support the practicality of applying high-strength materials.Along with these studies, Hong et al. [25] calculate and establish a carbon dioxide emission database of structural steel materials by using input-output analysis (e.g., deformed bars and H-beam).According to Hong et al. [25], an extremely important factor in the calculation of carbon dioxide of a material by adopting the input-output analysis involves considering manufacturing processes and the efficiency of manufacturing processes.If there are differences in the process and the energy efficiency of manufacturing in the same product, then the emission of CO 2 differs based on the two factors.Thus, both process and energy efficiency crucially impact the calculation of CO 2 on a certain material in the input-output analysis.Despite this approach to calculate CO 2 emissions of structural materials, it is necessary to study the effectiveness and relationships between the implementation of high-strength re-bars and normal re-bars.To fill this gap, this study examines the reduction of reinforcement bars and CO 2 emissions by the implementation of high-strength re-bars in three different structural types.

Calculating the Quantity of Re-Bars in the Different Building Structures
In this study, three different types of buildings, namely an office complex building, an apartment, and a residential-commercial complex building, were selected to compare the quantity variation in terms of reinforcing bars.The office complex building had a rigid-frame structure and is 25 storeys above the ground and one floor underground.The selected apartment building is one of the most popular hosing building types in South Korea and was constructed with a bearing wall system.The structure included 25 storeys aboveground and one floor underground with a mat footing system.The last model system was a residential-commercial complex building structure with a flat plate system.It included 43 floors aboveground and one floor for the basement with a mat footing system.A structural summary of the three models is indicated in Table 1.Additionally, the floor plans of the studied structures are shown in Figures 1-3.
Sustainability 2017, 9, 1652 5 of 23 footing system.A structural summary of the three models is indicated in Table 1.Additionally, the floor plans of the studied structures are shown in Figures 1-3.footing system.A structural summary of the three models is indicated in Table 1.Additionally, the floor plans of the studied structures are shown in Figures 1-3.Table 1.The profile of the studied models.2, the load factors, including seismic and wind loads, satisfied the Korean Building Code: Structure [27] as established by the Architectural Institute of Korea.Table 1.The profile of the studied models.

Calculation of Carbon Dioxide Emissions on Re-Bars by Using Yield Strength and Diameter
There are two approaches to establish Life Cycle Inventory (LCI) database: the individual integration method and the economic input-output analysis method [28].The individual integration method involves investigating a product's relevant data from manufacturing to demolition and subsequently accumulating the collected data of a product's energy consumption and carbon dioxide emissions.Normally, this method complies with ISO14044 [29] and ISO21930 [30] standards.Based on this, the system boundary of a target material, such as cradle-to-gate or cradle-to-grave, is applied to calculate the carbon dioxide emissions of a material.The economic input-output analysis method involves quantifying the industrial relationships of materials in an input-output matrix.
The input-output matrix represents all the interactions amongst industrial sectors in a comprehensive manner [19,[31][32][33][34][35][36][37].The data in the input-output matrix are normally derived from the National Statistics and Census data.For example, a glass panel manufacturer requires silica sand, other chemicals, and electricity.While direct suppliers perform measurements by analysing ingredients of glass, indirect suppliers, such as those for office equipment, papers, and others, might be excluded.Each unit of glass that is produced causes environmental discharges in other industry sectors that may range in several orders of magnitude.The input-output analysis method is expensive and time consuming, since inputs and environmental burdens must be collected either directly or obtained from extant studies, if they are available [33,36,37].Despite the above-mentioned difficulties in establishing the input-output analysis method of LCI, it is useful and efficient to predict the direct and indirect industrial impacts on the national economy [31,37].The input-output analysis method facilitates the calculation of energy consumption and carbon dioxide emissions.In this study, the economic input-output analysis was adopted as a method to obtain CO 2 emissions of normal strength reinforcement bars and high-strength reinforcement bars.
In this study, the input-output analysis was adopted to calculate the CO 2 emission of deformed bars using yield strength and diameter.This approach involves the analysis of relation of economic analysis based on the inter-dependencies of economic sectors [32,34].The basic assumption of the input-output analysis is that the production of a material is intertwined with several different processes and involves direct and indirect manufacturing such that the economic value analysis makes it possible to summarise the influx of material consumptions.To calculate the emission of CO 2 on re-bars, it is necessary to refer to production inducement coefficients and the unit price of materials [38].Table 3 shows production inducement coefficient of the structural steel [38].Additionally, Table 4 indicates the unit price of the reinforcing bars that were examined in this study [39].Based on the data shown in Table 5, the CO 2 emissions of the reinforcement bars on D10 were computed as 2526.611924kg-CO 2 /ton, 2648.867339, and 2726.295769kg-CO 2 /ton for SD400, SD500, and SD600, respectively.The CO 2 emissions of D13 and D16 re-bars exhibited a tendency similar to D10, as shown in Table 5.With respect to the D13 reinforcement bars, SD400, SD500, and SD600 emit carbon dioxide corresponding to 2485.860118, 2608.115534, and 2685.543964,respectively.The calculated results of D16 were 2461.409035,2608.115534, and 2665.169062 for SD400, SD500, and SD600, respectively.Generally, the emissions of carbon dioxide increased when the yield strength of the reinforcement bars was increased as shown in Figure 3.
Additionally, the emissions of CO 2 relative to variations in the diameter of reinforcement bars were compared as shown in Figure 4.The emissions of carbon dioxide decreased when the diameter of SD400 increased by D10, D13, and D13-D16.According to the computation results, SD400 with D10 corresponded to 2526.611924,D13 corresponded to 2485.860118, and D13-D16 corresponded to 2461.409035.This trend was similar to those of the other deformed bars (SD500 and SD600) while the diameter generally increased.

Analysis of the Quantity of Reinforcement Bars
The quantity variation of reinforcement bars in the three different structural types of buildings are shown in Table 6 and the detailed process of computing the quantity of each structure is displayed in Appendix A. The ratio of vertical to horizontal members in the rigid-frame structure (Rahmen structure) was approximately 35:65.When the normal strength reinforcement bars (SD400) were replaced with the high-strength bars (SD500 and SD600), beams or girders and footings were the most effective members with high-strength deformed bars in the rigid-frame structure.The reduction ratio of re-bars in beams or girders was 20.8% for SD500 and 32.0% for SD600, when compared with those of the normal strength deformed bars (SD400).Additionally, the results indicated 18% of quantity reduction ratio for SD500 when compared to SD400 and 21.2% decrease in quantity with SD600 when compared with SD400 reinforcing bars in footings.The quantity variation on the slabs increased when the high-strength deformed bars are implemented, as shown in Table 6.The computed results show that the quantity variation increased by 8.3% and 27.3% in for SD500 and SD600, respectively, when compared with those of SD400.While the amount of main reinforcement decreased when the high-strength re-bars were applied to slabs, thermal cracking control reinforcement was also used, although it was not required to resist the internal and external forces.
The reduction ratio of reinforcement bars in the apartment buildings was less effective than those of the other two structures.With respect to the total quantity reduction ratio of re-bars in the apartment buildings, the data show that 5.1% and 9.7% of reinforcement bars were reduced in the case of SD500 and SD600, respectively, when compared with those of SD400 re-bars.The highest reduction ratio in the bearing wall system (i.e., apartment buildings) corresponded to the footing.As shown in Table 6, the results show a 16.4% reduction ratio for SD500 and 26.8% reduction ratio for SD600 when compared with those of SD400 deformed bars.Conversely, the reduction ratio on walls in the apartment buildings was relatively smaller when compared with those of other components.

Analysis of the Quantity of Reinforcement Bars
The quantity variation of reinforcement bars in the three different structural types of buildings are shown in Table 6 and the detailed process of computing the quantity of each structure is displayed in Appendix A. The ratio of vertical to horizontal members in the rigid-frame structure (Rahmen structure) was approximately 35:65.When the normal strength reinforcement bars (SD400) were replaced with the high-strength bars (SD500 and SD600), beams or girders and footings were the most effective members with high-strength deformed bars in the rigid-frame structure.The reduction ratio of re-bars in beams or girders was 20.8% for SD500 and 32.0% for SD600, when compared with those of the normal strength deformed bars (SD400).Additionally, the results indicated 18% of quantity reduction ratio for SD500 when compared to SD400 and 21.2% decrease in quantity with SD600 when compared with SD400 reinforcing bars in footings.The quantity variation on the slabs increased when the high-strength deformed bars are implemented, as shown in Table 6.The computed results show that the quantity variation increased by 8.3% and 27.3% in for SD500 and SD600, respectively, when compared with those of SD400.While the amount of main reinforcement decreased when the high-strength re-bars were applied to slabs, thermal cracking control reinforcement was also used, although it was not required to resist the internal and external forces.
The reduction ratio of reinforcement bars in the apartment buildings was less effective than those of the other two structures.With respect to the total quantity reduction ratio of re-bars in the apartment buildings, the data show that 5.1% and 9.7% of reinforcement bars were reduced in the case of SD500 and SD600, respectively, when compared with those of SD400 re-bars.The highest reduction ratio in the bearing wall system (i.e., apartment buildings) corresponded to the footing.As shown in Table 6, the results show a 16.4% reduction ratio for SD500 and 26.8% reduction ratio for SD600 when compared with those of SD400 deformed bars.Conversely, the reduction ratio on walls in the apartment buildings was relatively smaller when compared with those of other components.The reduction ratio of reinforcing bars in the apartment building was the least amongst the three studied models.The apartment building with a bearing wall system accounts for more than 50% of reinforcement on walls.However, the amount of reduction on walls was lower than those of the other structural systems in this study.This could be because the vertical reinforcement is regulated by the minimum reinforcement and minimum area of re-bars as opposed to the internal forces of members.Thus, the reduction ratio of the horizontal members exceeded those of the vertical member since the reinforcement in the vertical members above certain floors was controlled by the minimum reinforcement ratio instead of the member's internal forces.Among the horizontal members, beams or girders and footings exhibited considerable lowering tendencies as well as similar reduction ratios.Conversely, slabs displayed a different trend of reduction ratio based on the size and yield strength of the deformed bars.The reason for this result could be due to the thermal cracking control reinforcement on slabs that did not indicate any reduction ratio, although the quantity of main reinforcement was lowered by a significantly high amount.

The Overview of the Total CO 2 Emissions
The total quantity of CO 2 emissions is the sum of carbon dioxide emissions from main components, which include slabs, beams or girders, walls, columns, and footings.For the office building with the rigid-frame structure, the emissions of CO 2 were reduced when high-strength reinforcement bars were applied in the structure.When the building was designed with SD500, the total quantity of CO 2 emissions was reduced by 8.92% when compared to those of SD400.Although the use of SD600 showed a slight increase in the carbon dioxide emissions, the emissions of CO 2 were reduced when compared to those of SD400.The application of SD600 re-bars indicated that the CO 2 emissions were lowered by 8.48% when compared to those of SD400.Thus, the application of SD600 reinforcement bars in the rigid-frame structure leads to a slight increase in CO 2 emissions (0.44%) when compared with the application of SD500 re-bars.In this study, the implementation of SD500 deformed bars in the rigid-frame structure corresponds to the most effective method to minimise the emissions of CO 2 (see Figure 5).regulated by the minimum reinforcement and minimum area of re-bars as opposed to the internal forces of members.Thus, the reduction ratio of the horizontal members exceeded those of the vertical member since the reinforcement in the vertical members above certain floors was controlled by the minimum reinforcement ratio instead of the member's internal forces.Among the horizontal members, beams or girders and footings exhibited considerable lowering tendencies as well as similar reduction ratios.Conversely, slabs displayed a different trend of reduction ratio based on the size and yield strength of the deformed bars.The reason for this result could be due to the thermal cracking control reinforcement on slabs that did not indicate any reduction ratio, although the quantity of main reinforcement was lowered by a significantly high amount.

The Overview of the Total CO2 Emissions
The total quantity of CO2 emissions is the sum of carbon dioxide emissions from main components, which include slabs, beams or girders, walls, columns, and footings.For the office building with the rigid-frame structure, the emissions of CO2 were reduced when high-strength reinforcement bars were applied in the structure.When the building was designed with SD500, the total quantity of CO2 emissions was reduced by 8.92% when compared to those of SD400.Although the use of SD600 showed a slight increase in the carbon dioxide emissions, the emissions of CO2 were reduced when compared to those of SD400.The application of SD600 re-bars indicated that the CO2 emissions were lowered by 8.48% when compared to those of SD400.Thus, the application of SD600 reinforcement bars in the rigid-frame structure leads to a slight increase in CO2 emissions (0.44%) when compared with the application of SD500 re-bars.In this study, the implementation of SD500 deformed bars in the rigid-frame structure corresponds to the most effective method to minimise the emissions of CO2 (see Figure 5).Although the reduction ratio of carbon dioxide in the bearing wall system structure (the apartment building) was relatively smaller than the other structures, it showed a reduced tendency with respect to the implementation of high-strength reinforcement bars.As shown in Figure 6, the application of SD500 and SD600 exhibits 0.47% and 2.30% reduction ratios of CO2, respectively, when compared with those of SD400.The residential-commercial complex building that was designed with the flat plate structure exhibited the most effective reduction ratio of CO2 among three different structures with the use of the high-strength reinforcement bars.The application of  Although the reduction ratio of carbon dioxide in the bearing wall system structure (the apartment building) was relatively smaller than the other structures, it showed a reduced tendency with respect to the implementation of high-strength reinforcement bars.As shown in Figure 6, the application of SD500 and SD600 exhibits 0.47% and 2.30% reduction ratios of CO 2 , respectively, when compared with those of SD400.The residential-commercial complex building that was designed with the flat plate structure exhibited the most effective reduction ratio of CO 2 among three different structures with the use of the high-strength reinforcement bars.The application of SD500 in the residential-commercial complex building showed similar results with the office building corresponding to a 7.53% reduction ratio when compared to the implementation of SD400 reinforcing bars.The CO 2 emissions from the application of SD600 re-bars were significantly lowered in the flat plate structure.The results indicated that the reduction ratio on SD600 when compared with that of SD400 was 13.76%.The CO 2 reduction ratio of each component in the three different structures is compared in the following section.SD500 in the residential-commercial complex building showed similar results with the office building corresponding to a 7.53% reduction ratio when compared to the implementation of SD400 reinforcing bars.The CO2 emissions from the application of SD600 re-bars were significantly lowered in the flat plate structure.The results indicated that the reduction ratio on SD600 when compared with that of SD400 was 13.76%.The CO2 reduction ratio of each component in the three different structures is compared in the following section.

CO2 Emissions on Slabs
The CO2 emissions of the residential-commercial complex building and the apartment building reduced when the high-strength reinforcement bars were applied to the slabs.The implementation to the residential-commercial complex building was significant because the reduction ratio was the highest among the three different structures.When the strength of the reinforcement bars increased due to SD500 and SD600, the reduction ratio reduced by 10.89% and 19.35%, respectively (see Figure 7).

CO 2 Emissions on Slabs
The CO 2 emissions of the residential-commercial complex building and the apartment building reduced when the high-strength reinforcement bars were applied to the slabs.The implementation to the residential-commercial complex building was significant because the reduction ratio was the highest among the three different structures.When the strength of the reinforcement bars increased due to SD500 and SD600, the reduction ratio reduced by 10.89% and 19.35%, respectively (see Figure 7).SD500 in the residential-commercial complex building showed similar results with the office building corresponding to a 7.53% reduction ratio when compared to the implementation of SD400 reinforcing bars.The CO2 emissions from the application of SD600 re-bars were significantly lowered in the flat plate structure.The results indicated that the reduction ratio on SD600 when compared with that of SD400 was 13.76%.The CO2 reduction ratio of each component in the three different structures is compared in the following section.

CO2 Emissions on Slabs
The CO2 emissions of the residential-commercial complex building and the apartment building reduced when the high-strength reinforcement bars were applied to the slabs.The implementation to the residential-commercial complex building was significant because the reduction ratio was the highest among the three different structures.When the strength of the reinforcement bars increased due to SD500 and SD600, the reduction ratio reduced by 10.89% and 19.35%, respectively (see Figure 7).With respect to the apartment building, the CO 2 emissions also reduced when the high-strength reinforcement bars were applied to slabs.The reduction ratio of CO 2 on SD500 and SD600 reinforcement bars was 92.40% and 96.13%, respectively.However, the reduction ratio of SD600 re-bars slightly increased compared with that of SD500 (which corresponded to 3.73%).This result was because of the high increase in the ratio for the input material of splice and development of slabs in the apartment building.
The reduction ratio of the office building was completely different between the two building types.An increase in the yield strength of re-bars caused the reduction ratio of CO 2 to exhibit an increasing tendency.The application of SD500 and SD600 deformed bars indicated increases corresponding to 13.58% and 37.35%, respectively, when compared with those of SD400.Hence, the quantity of splice and development was significantly higher than the quantity reduction in the main reinforcement on slabs in the office building.

CO 2 Emissions on Beams or Girders
The CO 2 emissions reduction ratio of beams or girders exhibited distinct characteristics based on the structural type of the building.With respect to an office building, the CO 2 emissions reduction ratio displayed a decreasing tendency when the high-strength reinforcement bars were applied to beams or girders.When SD500 re-bars were applied to the beams or girders in the apartment building, the reduction ratio achieved a 16.20% reduction ratio of CO 2 .Additionally, the results demonstrated a 26.06% reduced amount of carbon dioxide when the SD600 reinforcing bars were implemented (see Figure 8).
The residential-commercial complex building showed a slight increase in CO 2 emissions when high-strength re-bars were applied to the beams or girders.The use of SD500 and SD600 re-bars indicated 3.37% and 2.49% increase in CO 2 , respectively.This result can be used to analyse whether a difference exists between the utilisation of high-strength re-bars and normal re-bars for lowering the CO 2 emissions on beams in a residential-commercial complex building.
The last model (the apartment building) displayed a unique CO 2 reduction ratio movement.While the application of the SD500 deformed bars yielded an increase in CO 2 emissions of approximately 10%, the SD600 re-bars indicated a reduction in CO 2 emissions by 12.94%.This effect may be caused by a significant quantity reduction in splice and development by using SD600.With respect to the apartment building, the CO2 emissions also reduced when the high-strength reinforcement bars were applied to slabs.The reduction ratio of CO2 on SD500 and SD600 reinforcement bars was 92.40% and 96.13%, respectively.However, the reduction ratio of SD600 re-bars slightly increased compared with that of SD500 (which corresponded to 3.73%).This result was because of the high increase in the ratio for the input material of splice and development of slabs in the apartment building.
The reduction ratio of the office building was completely different between the two building types.An increase in the yield strength of re-bars caused the reduction ratio of CO2 to exhibit an increasing tendency.The application of SD500 and SD600 deformed bars indicated increases corresponding to 13.58% and 37.35%, respectively, when compared with those of SD400.Hence, the quantity of splice and development was significantly higher than the quantity reduction in the main reinforcement on slabs in the office building.

CO2 Emissions on Beams or Girders
The CO2 emissions reduction ratio of beams or girders exhibited distinct characteristics based on the structural type of the building.With respect to an office building, the CO2 emissions reduction ratio displayed a decreasing tendency when the high-strength reinforcement bars were applied to beams or girders.When SD500 re-bars were applied to the beams or girders in the apartment building, the reduction ratio achieved a 16.20% reduction ratio of CO2.Additionally, the results demonstrated a 26.06% reduced amount of carbon dioxide when the SD600 reinforcing bars were implemented (see Figure 8).
The residential-commercial complex building showed a slight increase in CO2 emissions when high-strength re-bars were applied to the beams or girders.The use of SD500 and SD600 re-bars indicated 3.37% and 2.49% increase in CO2, respectively.This result can be used to analyse whether a difference exists between the utilisation of high-strength re-bars and normal re-bars for lowering the CO2 emissions on beams in a residential-commercial complex building.
The last model (the apartment building) displayed a unique CO2 reduction ratio movement.While the application of the SD500 deformed bars yielded an increase in CO2 emissions of approximately 10%, the SD600 re-bars indicated a reduction in CO2 emissions by 12.94%.This effect may be caused by a significant quantity reduction in splice and development by using SD600.

CO 2 Emissions on Columns
The CO 2 reduction ratio for columns, as shown in Figure 9, were compared for the office and residential-commercial complex buildings since the structural system of an apartment building corresponds to a bearing wall system.Generally, buildings with a bearing wall system resist loads and external forces through the bearing walls without columns.

CO2 Emissions on Columns
The CO2 reduction ratio for columns, as shown in Figure 9, were compared for the office and residential-commercial complex buildings since the structural system of an apartment building corresponds to a bearing wall system.Generally, buildings with a bearing wall system resist loads and external forces through the bearing walls without columns.The office building with the rigid-frame structure and the residential-commercial complex with the flat-plate system exhibited a decreasing tendency of carbon dioxide emissions when the high-strength reinforcing bars were applied to the columns.In the office building, the application of SD500 exhibited 91.24% that corresponded to 8.76% reduced CO2 emissions when compared to SD400.The result for the use of SD600 showed 5.38% reduced CO2 emissions over SD400, although it slightly increased when compared to SD500.
Conversely, the application of the high-strength reinforcement bars in the residentialcommercial complex exhibited a gradual decrease of 8.77% and 17.31%, respectively, when the yield strength increased due to SD500 and SD600.A potential reason for this could be the design regulations of columns that are designed with respect to the minimum reinforcement ratio as opposed to the resistance of the internal forces on columns.This design practice leads to a significant reduction ratio of reinforcement bars on columns as well as a reduction in the carbon dioxide emissions.

CO2 Emissions on Footings
The CO2 emissions reduction ratio of footings in the three types of buildings showed a decreasing tendency when the strength of reinforcement bars increased (see Figure 10).Additionally, the reduction ratio of three different structures was significant when compared with other components in the building system.Thus, reductions in carbon dioxide emissions on footings in the rigid-frame structure, flat-plate structure, and bearing wall system may be desirable when the footing is designed by implementing the high-strength reinforcing bars.The implementation of SD500 for the footing indicated similar data around 80% that approximately corresponds to a 15% reduction in carbon dioxide emissions.Among the three structural systems, the reduction ratio of the office building was relatively smaller when SD600 re-bars were applied to footings.The others (i.e., the apartment building and the residential-commercial complex) exhibited approximately 30%  The office building with the rigid-frame structure and the residential-commercial complex with the flat-plate system exhibited a decreasing tendency of carbon dioxide emissions when the high-strength reinforcing bars were applied to the columns.In the office building, the application of SD500 exhibited 91.24% that corresponded to 8.76% reduced CO 2 emissions when compared to SD400.The result for the use of SD600 showed 5.38% reduced CO 2 emissions over SD400, although it slightly increased when compared to SD500.
Conversely, the application of the high-strength reinforcement bars in the residential-commercial complex exhibited a gradual decrease of 8.77% and 17.31%, respectively, when the yield strength increased due to SD500 and SD600.A potential reason for this could be the design regulations of columns that are designed with respect to the minimum reinforcement ratio as opposed to the resistance of the internal forces on columns.This design practice leads to a significant reduction ratio of reinforcement bars on columns as well as a reduction in the carbon dioxide emissions.

CO 2 Emissions on Footings
The CO 2 emissions reduction ratio of footings in the three types of buildings showed a decreasing tendency when the strength of reinforcement bars increased (see Figure 10).Additionally, the reduction ratio of three different structures was significant when compared with other components in the building system.Thus, reductions in carbon dioxide emissions on footings in the rigid-frame structure, flat-plate structure, and bearing wall system may be desirable when the footing is designed by implementing the high-strength reinforcing bars.The implementation of SD500 for the footing indicated similar data around 80% that approximately corresponds to a 15% reduction in carbon dioxide emissions.Among the three structural systems, the reduction ratio of the office building was relatively smaller when SD600 re-bars were applied to footings.The others (i.e., the apartment building and the residential-commercial complex) exhibited approximately 30% lowered CO 2 emissions of SD600 re-bars.In contrast, the data of the apartment building exhibited a reduction ratio approximately corresponding to 15%. lowered CO2 emissions of SD600 re-bars.In contrast, the data of the apartment building exhibited a reduction ratio approximately corresponding to 15%.Based on the results of this study, the rigid-frame structure and the flat plate structure are most effective when high-strength reinforcing bars were applied.Additionally, the effectiveness of SD500 reinforcement bars exceeded that of SD600 re-bars in the two structures.The application of SD600 yields a reduced amount of carbon dioxide emissions.However, the reduction ratio of SD600 slightly increased compared to the application of SD500 deformed bars.Therefore, the use of SD500 re-bars suggests that it is the most effective material for reducing carbon dioxide emissions in the examined models.Although the application of high-strength materials is beneficial in reducing the amount of input material, the utilisation of excessively high-strength materials has a detrimental influence, rather than creating sustainable and eco-friendly construction.Thus, the implementation of high-strength reinforcement bars is required in building structures to carefully design the optimal carbon dioxide emissions, as well as to improve constructability and workability in construction sites.

Discussion and Limitation
The aim of this study involved analysing quantity reduction and carbon dioxide emissions lowering ratio given the application of high-strength re-bars to the three different structural systems.
In this study, the application of high-strength reinforcing bars in three different structural would be beneficial compared to normal strength re-bars.Besides, the reduced amount of deformed bars would directly connect to the cost of material.The reduction ratio of high-strength reinforcing bars was higher than the increment ratio of unit cost as the yield strength of deformed bars was increased.
The study adopted the input-output analysis to calculate the carbon dioxide emissions of reinforcing bars by using the yield strength and diameter.While previous relevant studies examined CO2 emissions of steel or re-bars in a comprehensive manner, it may be difficult to calculate the occurrence of carbon dioxide emissions, effectiveness, or sustainability for an individual material.The method adopted in the study fills the above-mentioned gaps in evaluating CO2 emissions of deformed bars of different yield strength and diameter.Based on the results of this study, the rigid-frame structure and the flat plate structure are most effective when high-strength reinforcing bars were applied.Additionally, the effectiveness of SD500 reinforcement bars exceeded that of SD600 re-bars in the two structures.The application of SD600 yields a reduced amount of carbon dioxide emissions.However, the reduction ratio of SD600 slightly increased compared to the application of SD500 deformed bars.Therefore, the use of SD500 re-bars suggests that it is the most effective material for reducing carbon dioxide emissions in the examined models.Although the application of high-strength materials is beneficial in reducing the amount of input material, the utilisation of excessively high-strength materials has a detrimental influence, rather than creating sustainable and eco-friendly construction.Thus, the implementation of high-strength reinforcement bars is required in building structures to carefully design the optimal carbon dioxide emissions, as well as to improve constructability and workability in construction sites.

Discussion and Limitation
The aim of this study involved analysing quantity reduction and carbon dioxide emissions lowering ratio given the application of high-strength re-bars to the three different structural systems.
In this study, the application of high-strength reinforcing bars in three different structural would be beneficial compared to normal strength re-bars.Besides, the reduced amount of deformed bars would directly connect to the cost of material.The reduction ratio of high-strength reinforcing bars was higher than the increment ratio of unit cost as the yield strength of deformed bars was increased.
The study adopted the input-output analysis to calculate the carbon dioxide emissions of reinforcing bars by using the yield strength and diameter.While previous relevant studies examined CO 2 emissions of steel or re-bars in a comprehensive manner, it may be difficult to calculate the occurrence of carbon dioxide emissions, effectiveness, or sustainability for an individual material.The method adopted in the study fills the above-mentioned gaps in evaluating CO 2 emissions of deformed bars of different yield strength and diameter.
Furthermore, this study confirmed that the replacement normal strength reinforcing bars to high-strength ones in reinforced concrete structures and buildings would be one of alternatives for low-carbon buildings or green buildings.
Although the applied CO 2 calculation method in this study would contribute to evaluate the CO 2 emissions of re-bars, the results of CO 2 emissions using the input-output method exhibited slightly higher carbon dioxide emissions when compared with those in the individual integration method.
Furthermore, the input-output method is in a vulnerable position with respect to variations since the unit price of reinforcing bars changes based on the market situation.These factors may fluctuate the result of carbon dioxide emissions and deteriorate the reliability of the results.Thus, it is necessary to study or develop a new approach with respect to the CO 2 emissions for re-bars by strength or size to adjust the difference by using compensating factors or coefficients.
Moreover, further studies are necessary to compare the results of the individual integration method with those of the input-output method to verify the reliability and accuracy of the results of the latter approach.

Conclusions
This study calculated the quantity variation of reinforcing bars with increases in the yield strength, as well as calculated carbon dioxide emissions of the deformed bars.Based on the material quantity and the CO 2 emissions, the carbon dioxide reduction ratio of three different structural systems was compared to confirm the suitability and applicability of the high-strength reinforcing bars for lowering carbon dioxide emissions.The following results were obtained: 1.
A strength increase rate of SD500 and SD600 reinforcing bars when compared with that of SD400 was approximately 25% and 50%, respectively, and the reduction ratio of materials input on SD500 and SD600 re-bars was approximately 20% and 33%, respectively, when compared with those of SD400.

2.
The reinforcement quantity of SD500 and SD600 in compliance with the minimum reinforcement ratio in the flexural members and one-way structure was lowered by 20% and 30%, respectively, when compared to those of SD400 re-bars.

3.
When the high-strength reinforcing bars were applied to the three structural systems, the pure quantity of bar arrangement including upper and lower bar arrangement, stirrup, and hoop generally exhibited a decreasing tendency.Conversely, the quantity of splice and development increased when the strength of deformed bars increased.However, the total quantity of reinforcement bars exhibited a decrease, since the reduction ratio of pure quantity exceeded that of the increment in splice and development.

4.
Generally, applications to high-strength materials, especially high-strength deformed bars in the study is potentially beneficial in reducing the input amount of materials in the rigid-frame structure, bearing wall system, and flat-plate system. 5.
The results indicated that the implementation of SD500 deformed bars was the most effective in reducing carbon dioxide emissions.Thus, the excessive pursuit of high-strength materials detrimentally impacts carbon dioxide emissions.Hence, it is necessary to carefully calculate and compare the trade-off between material reduction and CO 2 emissions for sustainable structures and buildings.

Figure 1 .Figure 2 .
Figure 1.Floor plans of the office complex building: (a) typical floor; and (b) basement floor.

Figure 1 .
Figure 1.Floor plans of the office complex building: (a) typical floor; and (b) basement floor.

Figure 1 .Figure 2 .
Figure 1.Floor plans of the office complex building: (a) typical floor; and (b) basement floor.

Figure 2 .
Figure 2. Floor plans of the apartment building: (a) typical floor; and (b) basement floor.

Figure 3 .
Figure 3. Floor plans of the residential complex building: (a) typical floor; and (b) baseent floor.

(
Horizontal members and footing) The three models were designed in compliance with Structural Concrete Design Code and Commentary by Korea Concrete Institute [26].As shown in Table

Figure 3 .
Figure 3. Floor plans of the residential complex building: (a) typical floor; and (b) baseent floor.
) f ck = 30-50 MPa (Vertical members) f ck = 30-36 MPa (Horizontal members and footing) The three models were designed in compliance with Structural Concrete Design Code and Commentary by Korea Concrete Institute [26].As shown in Table2, the load factors, including seismic and wind loads, satisfied the Korean Building Code: Structure[27] as established by the Architectural Institute of Korea.

Figure 4 .
Figure 4. CO2 emissions of re-bars by yield strength.

Figure 4 .
Figure 4. CO 2 emissions of re-bars by yield strength.

Figure 5 .
Figure 5.Total CO2 emissions of the studied models.

Figure 5 .
Figure 5.Total CO 2 emissions of the studied models.

Table 2 .
The factors of seismic and wind loads.

Table 2 .
The factors of seismic and wind loads.

Table 3 .
Production inducement coefficient of structural steel.

Table 4 .
The unit price of steel re-bars (Unit price: KRW).

Table 5
displays the energy consumption and CO 2 emissions of deformed bars by yield strength and diameter.The detailed explanation of calculating the CO 2 emissions by yield strength and diameter is shown in Appendix B.

Table 5 .
Energy consumption and CO 2 emissions of re-bars.

Table 6 .
Total quantity of re-bars in the studied models (Unit: ton).