The use of recycled aggregates (RA) derived from construction and demolition waste (CDW) offers a viable alternative to natural aggregates (NA), with potential to reduce reliance on virgin resources. However, the effective utilization of RA requires integrated process design to mitigate the adverse effects of adhered mortar and interfacial heterogeneity. This study proposes an integrated multi-stage treatment framework for RA, combining mild chemical pre-soaking, controlled mechanical abrasion, and pressurized carbonation, with emphasis on process sequencing and threshold-based optimization. Raw RA was soaked in a mild acetic acid solution for 24 h, mechanically processed using a Los Angeles abrasion test machine (LAATM) at rotation levels ranging from 0 to 600, and subsequently subjected to 2 h of pressurized carbonation. The resulting combinedly treated recycled aggregates (CTRAs) were incorporated into M40-grade concrete at replacement levels of 0%, 20%, 40%, 60%, 80%, and 100%. Mechanical performance was evaluated through compressive and splitting tensile strength tests. The results indicate the existence of a critical mechanical processing window at approximately 500 LAATM rotations, beyond which further processing provides diminishing benefits. Concrete incorporating 60% CTRA processed at 500 rotations exhibited a reduction of 17.34% in compressive strength and approximately 16% in splitting tensile strength relative to natural aggregate concrete, while maintaining stable performance trends within the investigated scope. These findings demonstrate that coordinated treatment sequencing and processing intensity, rather than isolated treatment steps, govern the mechanical response of recycled aggregate concrete, supporting a concurrent engineering approach to recycled aggregate system design.
AbbasAFathifazlGIsgorOB, et al. (2006) Environmental benefits of green concrete. 2006 IEEE EIC Climate Change Technology Conference, EICCCC 2006. Available at. https://doi.org/10.1109/EICCCC.2006.277204
2.
AkhtarASarmahAK (2018) Construction and demolition waste generation and properties of recycled aggregate concrete: a global perspective. Journal of Cleaner Production186: 262–281.
3.
Al-BayatiHKADasPKTigheSL, et al. (2016) Evaluation of various treatment methods for enhancing the physical and morphological properties of coarse recycled concrete aggregate. Construction and Building Materials112: 284–298.
4.
BabuVSMullickAJainK, et al. (2014a) Mechanical properties of high strength concrete with recycled aggregate-influence of processing. Indian Concrete Journal88(5): 10–26.
5.
BabuVSMullickAJainK, et al. (2014b) Strength and durability characteristics of high-strength concrete with recycled aggregate-influence of processing. Journal of Sustainable Cement-Based Materials4(1): 54–71.
6.
BabuVSMullickAJainK, et al. (2014c) Mechanical properties of high strength concrete with processed recycled aggregate - influence of mixing techniques. Indian Concrete Journal88(10): 42–56.
7.
BabuVSMullickAJainK, et al. (2014d) Strength and durability characteristics of high-strength concrete with recycled aggregate – influence of mixing techniques. Journal of Sustainable Cement-Based Materials3(2): 88–110.
8.
BaiGZhuCLiuC, et al. (2020) An evaluation of the recycled aggregate characteristics and the recycled aggregate concrete mechanical properties. Construction and Building Materials240: 117978.
9.
BhikshmaVManipalK (2012) Study on mechanical properties of recycled aggregate concrete containing steel fibers. Asian Journal of Civil Engineering13(2): 155–164.
10.
Ccanz (2011) Best Practice Guide for the use of Recycled Aggregates in New Concrete. Production.
11.
CEDEX, Ministerio de Fomento and Ministerio de Medio Ambiente (2014) Catálogo de Residuos Utilizables en Construcción. Ficha técnica residuos de construcción y demolición’, Cedex, pp. 1–54.
12.
Chakradhara RaoMBhattacharyyaSKBaraiSV (2011a) Behaviour of recycled aggregate concrete under drop weight impact load. Construction and Building Materials25(1): 69–80.
13.
Chakradhara RaoMBhattacharyyaSKBaraiSV (2011b) Influence of field recycled coarse aggregate on properties of concrete. Materials and Structures/Materiaux et Constructions44(1): 205–220.
14.
Cupo-PaganoMD’andreaAGiavariniC, et al. (1994) Use of building demolition waste for asphalt mixes: first results’. In Energy, Environment and Technological Innovation. In Proceedings of III International Congress of Energy, Environment and Technological Innovation, pp. 203–208.
15.
de JuanMSGutiérrezPA (2009) Study on the influence of attached mortar content on the properties of recycled concrete aggregate. Construction and Building Materials23(2): 872–877.
16.
DilbasH (2023) Optimizing the treatment of recycled aggregate (>4 mm), artificial intelligence and analytical approaches. Materials16(8): 2994.
17.
DimitriouGSavvaPPetrouMF (2018) Enhancing mechanical and durability properties of recycled aggregate concrete. Construction and Building Materials158: 228–235.
18.
EtxeberriaMVázquezEMaríA, et al. (2007) Influence of amount of recycled coarse aggregates and production process on properties of recycled aggregate concrete. Cement and Concrete Research37(5): 735–742.
19.
EvangelistaLde BritoJ (2007) Mechanical behaviour of concrete made with fine recycled concrete aggregates. Cement and Concrete Composites29(5): 397–401.
20.
FerreiraLDe BritoJBarraM (2011) Influence of the pre-saturation of recycled coarse concrete aggregates on concrete properties. Magazine of Concrete Research63(8): 617–627.
21.
GoliyaRKBabuVS (2023) Performance evaluation of concrete made with double-processed recycled aggregate (DPRA): mechanical grinding and silica fume impregnation technique. Journal of Material Cycles and Waste Management25(2): 1050–1068.
22.
JiménezJRAgrelaFAyusoJ, et al. (2011) Estudio comparativo de los áridos reciclados de hormigón y mixtos como material para sub-bases de carreteras. Materiales de Construcción61(302): 289–302.
23.
KangMWeibinL (2018) Effect of the aggregate size on strength properties of recycled aggregate concrete. Advances in Materials Science and Engineering2018: 2428576.
24.
KatzA (2003) Properties of concrete made with recycled aggregate from partially hydrated old concrete. Cement and Concrete Research33(5): 703–711.
25.
KatzA (2004) Treatments for the improvement of recycled aggregate. Journal of Materials in Civil Engineering16(6): 597–603.
26.
KhoshkenariAGShafighPMoghimiM, et al. (2014) The role of 0-2mm fine recycled concrete aggregate on the compressive and splitting tensile strengths of recycled concrete aggregate concrete. Materials and Design64: 345–354.
27.
KouSCPoonCSAgrelaF (2011) Comparisons of natural and recycled aggregate concretes prepared with the addition of different mineral admixtures. Cement and Concrete Composites33(8): 788–795.
28.
LeiteFDCMottaRSVasconcelosKL, et al. (2011) Laboratory evaluation of recycled construction and demolition waste for pavements. Construction and Building Materials25(6): 2972–2979.
29.
LiX (2009) Recycling and reuse of waste concrete in China. Part II. Structural behaviour of recycled aggregate concrete and engineering applications. Resources, Conservation and Recycling53(3): 107–112.
30.
LimbachiyaMSeddik MeddahMOuchagourY (2012) Performance of portland/silica fume cement concrete produced with recycled concrete aggregate. ACI Materials Journal109(1): 91–100.
31.
Mills-BealeJYouZ (2010) The mechanical properties of asphalt mixtures with recycled concrete aggregates. Construction and Building Materials24(3): 230–235.
32.
MongelliM (2018) Serial fundal height measurements for gestational age estimation. BJOG: An International Journal of Obstetrics and Gynaecology125(11): 1405.
33.
MukharjeeBBBaraiSV (2017) Mechanical and microstructural characterization of recycled aggregate concrete containing silica nanoparticles. Journal of Sustainable Cement-Based Materials6(1): 37–53.
34.
OtsukiNMiyazatoSYodsudjaiW (2003) Influence of recycled aggregate on interfacial transition zone, strength, chloride penetration and carbonation of concrete. Journal of Materials in Civil Engineering15(5): 443–451.
35.
ParanavithanaSMohajeraniA (2006) Effects of recycled concrete aggregates on properties of asphalt concrete. Resources, Conservation and Recycling48(1): 1–12.
36.
PasandínARPérezI (2013) Laboratory evaluation of hot-mix asphalt containing construction and demolition waste. Construction and Building Materials43: 497–505.
37.
PasandínARPérezI (2014a) Effect of ageing time on properties of hot-mix asphalt containing recycled concrete aggregates. Construction and Building Materials52: 284–293.
38.
PasandínARPérezI (2014b) Adhesion of recycled concrete aggregates, demolition debris, and asphalt. Petroleum Science and Technology32(21): 2584–2591.
39.
PérezIPasandínARGallegoJ (2012a) Stripping in hot mix asphalt produced by aggregates from construction and demolition waste. Waste Management & Research30(1): 3–11.
40.
PérezIPasandínARMedinaL (2012b) Hot mix asphalt using C&D waste as coarse aggregates. Materials and Design36: 840–846.
41.
PoonCSShuiZHLamL (2004) Effect of microstructure of ITZ on compressive strength of concrete prepared with recycled aggregates. Construction and Building Materials18(6): 461–468.
42.
PurohitBDSamaiyaNK and Verma A (2025b) ‘Properties of concrete incorporating recycled aggregate processed via a novel three-stage technique’, Proceedings of the Institution of Civil Engineers - Engineering Sustainability, pp. 1–27. Available at:https://doi.org/10.1680/jensu.25.00061
43.
PurohitBDSamaiyaNKVermaA (2025a) Characterisation of recycled aggregate processed through pre-soaking, mechanical grinding and layered coating of aggregates: a three-stage processing technique. Australian Journal of Structural Engineering1–16.
44.
RafiMMQadirASiddiquiSH (2011) Experimental testing of hot mix asphalt mixture made of recycled aggregates. Waste Management & Research29(12): 1316–1326.
45.
RodriguesFCarvalhoMTEvangelistaL, et al. (2013) Physical-chemical and mineralogical characterization of fine aggregates from construction and demolition waste recycling plants. Journal of Cleaner Production52: 438–445.
46.
Sai TrivediSSnehalKDasB, et al. (2023) A comprehensive review towards sustainable approaches on the processing and treatment of construction and demolition waste. Construction and Building Materials393: 132125.
47.
Salcedo FontalvoJEVega AraujoDLAriza PoloL, et al. (2023) Influence of recycled concrete aggregates on the California Bearing Ratio (CBR) of granular sub-bases. Arabian Journal for Science and Engineering48(10): 14095–14104.
48.
ShenDHDuJC (2004) Evaluation of building materials recycling on HMA permanent deformation. Construction and Building Materials18(6): 391–397.
49.
ShenD-HDuJ-C (2005) Application of gray relational analysis to evaluate HMA with reclaimed building materials. Journal of Materials in Civil Engineering17(4): 400–406.
50.
SilvaRVDe BritoJDhirRK (2015a) The influence of the use of recycled aggregates on the compressive strength of concrete: a review. European Journal of Environmental and Civil Engineering19(7): 825–849.
51.
SilvaRVDe BritoJDhirRK (2015b) Tensile strength behaviour of recycled aggregate concrete. Construction and Building Materials83: 108–118.
52.
SinghSSinghSKMahgoubM, et al. (2024) Evaluating recycled concrete aggregate and sand for sustainable construction performance and environmental benefits. CivilEng5(2): 461–481.
53.
SpaethVDjerbi TegguerA (2013) Improvement of recycled concrete aggregate properties by polymer treatments. International Journal of Sustainable Built Environment2(2): 143–152.
54.
SuYYaoYWangY, et al. (2023) Modification of recycled concrete aggregate and its use in concrete: an overview of research progress. Materials16: 7144.
55.
TamVWYTamCM (2007a) Assessment of durability of recycled aggregate concrete produced by two-stage mixing approach. Journal of Materials Science42: 3592–3602.
56.
TamVWYTamCM (2007b) Crushed aggregate production from centralized combined and individual waste sources in Hong Kong. Construction and Building Materials21(4): 879–886.
57.
TamVWYWangKTamCM (2008) Assessing relationships among properties of demolished concrete, recycled aggregate and recycled aggregate concrete using regression analysis. Journal of Hazardous Materials152(2): 703–714.
58.
Tugrul TuncEEsat AlyamacK (2019) A preliminary estimation method of Los Angeles abrasion value of concrete aggregates. Construction and Building Materials222: 437–446.
59.
VermaABabuVSSrinivasanA (2021a) Strength and durability properties of treated recycled aggregate concrete by soaking and mechanical grinding method: influence of processing technique. Journal of Materials in Civil Engineering33(10): 04021286.
60.
VermaASarath BabuVArunachalamS (2021b) Influence of mixing approaches on strength and durability properties of treated recycled aggregate concrete. Structural Concrete22(S1): E121–E142.
61.
VermaA.BabuV.S.ArunachalamS. (2022) ‘Influence of acetic acid soaking and mechanical grinding treatment on the properties of treated recycled aggregate concrete’, Journal of Material Cyclesand Waste Management [Preprint], (0123456789). Available at:https://doi.org/10.1007/s10163-022-01360-6
62.
VermaABabuVSSA (2022a) Influence of modified two-stage mixing approaches on recycled aggregate treated with a hybrid method of treatment. Australian Journal of Structural Engineering23(3): 230–253.
63.
VermaAVelagaBSArunachalamS (2022b) Performance evaluation of concrete using treated recycled aggregates modified with mineral admixtures: influence of processing. European Journal of Environmental and Civil Engineering0(0): 1–30.
64.
WangJZhangJCaoD, et al. (2020) Comparison of recycled aggregate treatment methods on the performance for recycled concrete. Construction and Building Materials234: 117366.
65.
XiaoJLiWPoonC (2012) Recent studies on mechanical properties of recycled aggregate concrete in China-A review. Science China Technological Sciences55(6): 1463–1480.
66.
ZegaCJDi MaioAA (2009) Recycled concrete made with different natural coarse aggregates exposed to high temperature. Construction and Building Materials23(5): 2047–2052.
