Abstract
This experimental research has been conducted to improve the mechanical properties of the problematic expansive soil using copper slag. The copper slag has been utilized to improve the Talab soil in Nainwa for the first time. The swelling properties show that the collected soil has a high degree of expansive nature and low specific gravity. Therefore, the copper slag has been added to the soil from 5% to 30% at a 5% variation by its oven-dry weight. The experimental results reveal that the free swell index of soil has decreased by 69.88% with the addition of 30% copper slag. It has also been observed that the liquid and plastic limits have been decreased. The plastic limit of soil decreases, because copper slag takes place in voids. Due to this phenomenon, the maximum dry density of soil has been increased by 14.75% with the addition of 25% copper slag. The California bearing ratio (CBR) value of soil has been increased to 1.13% (soaked condition) and 3.8% (unsoaked condition) by adding 25% copper slag. This research introduces an empirical relationship between unsoaked and soaked CBR with a determination coefficient (R2) of 0.8254. Moreover, it has been observed that the unconfined compressive strength of soil has increased by 51.68% with the addition of 25% copper slag. Furthermore, the value of R2 for the experimental results obtained in this research is higher than the published experimental results, presenting the experimental study’s accuracy and reliability. In addition, the analysis of variance (ANOVA) test accepts the research hypothesis for the present investigation.
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References
Ahirwar SK, Mandal JN (2021) Experimental study on bamboo grid-reinforced copper slag overlying soft subgrade. Constr Build Mater 306:124758. https://doi.org/10.1016/j.conbuildmat.2021.124758
Alemshet D, Fayissa B, Geremew A, Chala G (2023) Amelioration effect of fly ash and powdered ground steel slag for improving expansive subgrade soil. J Eng. https://doi.org/10.1155/2023/1652373
Arora KR (2008) Soil mechanics and foundation engineering (geotechnical engineering): In SI units. Standard Publishers, India
Ashokbhai BM, Rajubhai JK, Amarabhai SP, Chavda MM (2018) Utilization of copper slag to improve geotechnical properties of soil. Int Res J Eng Technol 5:666–673
Azad NM, Samarakoon SSM (2021) Utilization of industrial by-products/waste to manufacture geopolymer cement/concrete. Sustainability 13(2):873. https://doi.org/10.3390/su13020873
Balogun FO, Abzal A, Kissambinova A, Shon CS, Kim JR (2023) Stabilization of high sulfate-saline soil with lime, ground granulated blast furnace slag (GGBFS), and basic oxygen furnace slag (BOFS). Key Eng Mater 951:125–131. https://doi.org/10.4028/p-6JocPX
Bharti G, Hurukadli P, Shukla BK, Sihag P, Jagudi S, Tripathi A (2023) Environmental impact analysis and utilization of copper slag for stabilising black cotton soil. Mater Today Proc. https://doi.org/10.1016/j.matpr.2023.04.305
Debnath D, Chouksey SK (2022) Experimental study of strength behavior of soft soil stabilised with alkali-activated copper slag. Mater Today Proc 65:2112–2117. https://doi.org/10.1016/j.matpr.2022.07.106
Dinesh A, Indhumathi S, Pichumani M (2021) Performance assessment of copper slag and sawdust ash in stabilization of black cotton soil. In: Biswas S, Metya S, Kumar S, Samui P (eds) Advances in sustainable construction materials: select proceedings of ASCM 2020. Springer Singapore, Singapore, pp 213–227
Ekinci A, Scheuermann Filho HC, Consoli NC (2022) Copper slag–hydrated lime–Portland cement stabilised marine-deposited clay. Proc Inst Civil Eng Ground Improvement 175(1):51–63. https://doi.org/10.1680/jgrim.18.00123
Fakhrabadi A, Ghadakpour M, Choobbasti AJ, Kutanaei SS (2021) Influence of the non-woven geotextile (NWG) on the engineering properties of clayey-sand treated with copper slag-based geopolymer. Constr Build Mater 306:124830. https://doi.org/10.1016/j.conbuildmat.2021.124830
Fakhrabadi A, Choobbasti AJ, Kutanaei SS (2023) Durability evaluation of clayey sandy soil stabilized with copper-slag-based geopolymer under freezing-thawing cycles. Int J Pavement Res Technol. https://doi.org/10.1007/s42947-023-00341-8
Gobinath R, Akinwumi I, Ganapathy GP, Mithuna R (2021) Compaction and shear strength enhancement of weak soil by copper slag addition. Mater Today Proc 39:834–838
Hemanth TRSS, Sharma V (2023) Strength and compaction behavior of copper slag-stabilized soil. Mater Today Proc. https://doi.org/10.1016/j.matpr.2023.08.159
Hosseini S, Khatti J, Taiwo BO, Fissha Y, Grover KS, Ikeda H, Pushkarna M, Berhanu M, Ali M (2023) Assessment of the ground vibration during blasting in mining projects using different computational approaches. Sci Rep 13(1):18582. https://doi.org/10.1038/s41598-023-46064-5
I Standard (1977) IS: 2720 (Part XL)-1977: methods of test for soils: part XL determination of free swell index of soils. Bureau of Indian Standards, India
I Standard (1980a) IS: 2720 (part III/Sec 1)-1980: methods of test for soils: part III determination of specific gravity. Bureau of Indian Standards, India
I Standard (1980b) IS: 2720 (Part VII)-1980: methods of test for soils: part VII determination of water content-dry density relation using light compaction. Bureau of Indian Standards, India
I Standard (1985) IS: 2720 (Part IV)-1985: methods of test for soils: part 5 determination of liquid and plastic limit. Bureau of Indian Standards, India
I Standard (1987) IS: 2720 (part 16)-1987: methods of test for soils: part 16 laboratory determination of CBR. Bureau of Indian Standards, India
I Standard (1991) IS: 2720 (Part 10)-1991: methods of test for soils: part 10 determination of unconfined compressive strength. Bureau of Indian Standards, India
I Standard (1975) IS: 2720 (part IV)-1975: methods of test for soils: part 4 grain size analysis. Bureau of Indian Standards, India
Jagudi S (2020) Improvement in behaviour of black cotton soil using copper slag and steel slag. Doctoral dissertation, National Institute of Technology, Kurukshetra
JanalizadehChoobbasti A, Farrokhzad F, Nadimi A, Soleimani Kutanaei S (2019) Effects of copper sludge on cemented clay using ultrasonic pulse velocity. J Adhes Sci Technol 33(4):433–444. https://doi.org/10.1080/01694243.2018.1471842
Kabeta WF, Lemma H (2023) Modeling the application of steel slag in stabilizing expansive soil. Model Earth Syst Environ. https://doi.org/10.1007/s40808-023-01734-1
Kavisri M, Senthilkumar P, Gurukumar MS, Pushparaj KJ (2018) Experimental study on effects of stabilization of clayey soil using copper slag and GGBS. Rasayan J Chem 11:111–117
Khatti J, Grover KS (2021a) Prediction of suitable percentage of waste materials for improving geotechnical properties of black cotton soil using AI approaches. In: Muthukkumaran K, Jakka RS, Parthasarathy CR, Soundara B (eds) Indian geotechnical conference. Springer Nature Singapore, Singapore, pp 43–57
Khatti J, Grover KS (2021b) Relationship between index properties and CBR of soil and prediction of CBR. In: Muthukkumaran K, Rathod D, Sujatha ER, Muthukumar M (eds) Indian geotechnical conference. Springer Nature Singapore, Singapore, pp 171–185
Khatti J, Grover K (2022) A study of relationship among correlation coefficient, performance, and overfitting using regression analysis. Int J Sci Eng Res 13:1074–1085
Khatti J, Grover KS (2023) Prediction of compaction parameters for fine-grained soil: critical comparison of the deep learning and standalone models. J Rock Mech Geotechn Eng. https://doi.org/10.1016/j.jrmge.2022.12.034
Khatti J, Samadi H, Grover KS (2023) Estimation of settlement of pile group in clay using soft computing techniques. Geotechn Geol Eng. https://doi.org/10.1007/s10706-023-02643-x
Kirithika M, Stalin VK (2019) Influence of nano copper slag in strength behaviour of lime stabilized soil. Geotechn Eng 50(4):34–38
Kumar PR, Kumar PSP, Maheswari G (2017) Laboratory study of black cotton soil blended with copper slag and fly ash. Int J Innov Res Sci Eng Technol 6(2):19601967
Kumar KB, Krishna G, Umashankar B (2019) Evaluation of waste foundry sand and blast furnace steel slag as geomaterials. Eighth international conference on case histories in geotechnical engineering. American Society of Civil Engineers, Reston, VA, pp 304–313
Lavanya C, Kumar ND (2021a) Study on CBR of lime and cement stabilized copper slag cushion laid over expansive soil. In: Patel S, Solanki CH, Reddy KR, Shukla SK (eds) Proceedings of the Indian geotechnical conference 2019: IGC-2019, vol V. Springer Singapore, Singapore, pp 129–139
Lavanya C, Kumar ND (2021b) Effect of lime-stabilised copper slag cushion on swelling behaviour of highly plastic clay. Geotechn Res 9(1):15–22. https://doi.org/10.1680/jgere.21.00006a
Li H, Cui C, Sheng Y, Zhang M, Feng Z, Li L, Xue H, Zhang Y (2023) Application of composite steel slag as subgrade filler: performance evaluation and enhancement. Constr Build Mater 370:130448. https://doi.org/10.1016/j.conbuildmat.2023.130448
Mabroum S, Moukannaa S, El Machi A, Taha Y, Benzaazoua M, Hakkou R (2020) Mine wastes based geopolymers: a critical review. Clean Eng Technol 1:100014. https://doi.org/10.1016/j.clet.2020.100014
Mahmoudi Kordi A, Toufigh V (2019) Sandy soil stabilization with copper slag-based geopolymer and copper slag and silica fume blend geopolymer. Sharif J Civil Eng 35(11):129–138. https://doi.org/10.24200/j30.2018.1999.2057
Mathew A, Sivaramakrishnan N, Cyrus S, Kavitha M (2019) A study on effect of additives on strength characteristics of marine clay. In: Drück H, Pillai RG, Tharian MG, Majeed AZ (eds) Green buildings and sustainable engineering: proceedings of GBSE 2018. Springer Singapore, Singapore, pp 445–455
Muthukkumaran K, Anusudha V (2020) Study on behavior of copper slag and lime-treated clay under static and dynamic loading. J Mater Civ Eng 32(8):04020230. https://doi.org/10.1061/(ASCE)MT.1943-5533.0003259
Panda N, Sahoo S, Jena H (2023) Performance of highway subgrade soil stabilized with lime and slag. In: Upadhyay RK, Sharma SK, Kumar V, Valera H (eds) Transportation systems technology and integrated management. Springer Nature Singapore, Singapore, pp 215–229
Pandya P, Kamdar B (2021) An experimental investigation of properties of black cotton soil treated with copper slag and groundnut shell powder. In: Proceedings of the Indian Geotechnical Conference 2019: IGC-2019, Volume III. Springer Singapore, pp. 815–823
Punmia BC, Kumar A, Jain AK (2001) Soil mechanics and foundation engineering. Standard Book House, New Delhi, pp 1–121
Qureshi MA, Mistry HM, Patel VD (2015) Improvement in soil properties of expansive soil by using copper slag. Int J Adv Res Eng Sci Technol 2(7):125–130
Raj S, Rai AK, Havanagi VG (2018) Suitability of stabilized copper slag and fly ash mix for road construction. World J Eng 15(3):336–344. https://doi.org/10.1108/WJE-08-2017-0220
Razali R, Rashid ASA, Lat DC, Horpibulsuk S, Roshan MJ, Rahman NSA, Rizal NHA (2023) Shear strength and durability against wetting and drying cycles of lime-stabilised laterite soil as subgrade. Phys Chem Earth Parts A/B/C 132:103479. https://doi.org/10.1016/j.pce.2023.103479
Reddy BV (2012) Stabilised soil blocks for structural masonry in earth construction. Modern earth buildings. Woodhead Publishing, UK, pp 324–363
Reddy CNV, Reddy R (2020) Copper slag potential for use as backfill/fill material in conventional and reinforced earth retaining walls. Indian J Geosynth Ground Improvement 9(1):46–51
Reddy CS, Reddy RDK, Nagalakshmi M (2023) Study on design of reinforced earth retaining wall with copper slag as fill material. In: Muthukkumaran K, Umashankar B, Pitchumani NK (eds) Earth retaining structures and stability analysis: proceedings of the Indian geotechnical conference 2021 volume 6, vol 303. Springer Nature, Singapore, p 279
Reshmi G, Mandal A (2019) Ground improvement using industrial waste materials. In: Sundaram R, Shahu JT, Havanagi V (eds) Geotechnics for transportation infrastructure: recent developments, upcoming technologies and new concepts, vol 2. Springer Singapore, Singapore, pp 473–486
Rogers JD, Olshansky R, Rogers RB (1993) Damage to foundations from expansive soils. Claims People 3(4):1–4
Roshan MJ, Rashid ASA, Wahab NA, Tamassoki S, Jusoh SN, Hezmi MA, Daud NNN, Apandi NM, Azmi M (2022a) Improved methods to prevent railway embankment failure and subgrade degradation: a review. Transport Geotechn 37:100834. https://doi.org/10.1016/j.trgeo.2022.100834
Roshan MJ, Rashid ASBA, Hezmi MAB, Nejabi MN, BtJusoh SN, Tamassoki S, Razali R (2022b) Evaluation of cement stabilised residual soil on macro-and micro-scale for road construction. J Eng Appl Sci 69(1):109. https://doi.org/10.1186/s44147-022-00165-6
Selvakumar S, Soundara B (2020) Swelling behavior of expansive soils stabilized with expanded polystyrene geofoam inclusion. New materials in civil engineering. Butterworth-Heinemann, Oxford, pp 745–776
Sharma K, Kumar A (2020) Utilization of industrial waste-based geopolymers as a soil stabilizer—a review. Innov Infrastruct Solut 5:1–20. https://doi.org/10.1007/s41062-020-00350-7
Sharma K, Kumar A (2022) Investigation of compaction, specific gravity, unconfined compressive strength and cbr of a composite having copper slag and rice husk ash mixed using an alkali activator. Innov Infrastruct Solut 7(2):185. https://doi.org/10.1007/s41062-022-00783-2
Soni J, Chokshi T, Sharma R, Gujar R, Jariwala N, Pitroda JR (2022) Assessing the applicability of fine copper slag in road and structural fill application. Mater Today Proc 62:7040–7043. https://doi.org/10.1016/j.matpr.2022.01.058
Stefanini L, Ghorbani S, De Schutter G, Matthys S, Walkley B, Provis JL (2023) Evaluation of copper slag and stainless-steel slag as replacements for blast furnace slag in binary and ternary alkali-activated cements. J Mater Sci 58(31):12537–12558. https://doi.org/10.1007/s10853-023-08815-7
Tajaddini A, Saberian M, Sirchi VK, Li J, Maqsood T (2023) Improvement of mechanical strength of low-plasticity clay soil using geopolymer-based materials synthesized from glass powder and copper slag. Case Stud Construct Mater 18:e01820. https://doi.org/10.1016/j.cscm.2022.e01820
Tamassoki S, Daud NNN, Jakarni FM, Kusin FM, Rashid ASA, Roshan MJ (2022a) Compressive and shear strengths of coir fibre reinforced activated carbon stabilised lateritic soil. Sustainability 14(15):9100. https://doi.org/10.3390/su14159100
Tamassoki S, Nik Daud NN, Jakarni FM, MohdKusin F, Rashid ASA, Roshan MJ (2022b) Performance evaluation of lateritic subgrade soil treated with lime and coir fibre—activated carbon. Appl Sci 12(16):8279. https://doi.org/10.3390/app12168279
Tamassoki S, Daud NNN, Wang S, Roshan MJ (2023) CBR of stabilized and reinforced residual soils using experimental, numerical, and machine-learning approaches. Transport Geotechn 42:101080. https://doi.org/10.1016/j.trgeo.2023.101080
Tandel YK, Patel JB (2009) Review of utilisation of copper slag in highway construction. Austral Geomech 44(3):71
Tanyıldızı M, Uz VE, Gökalp İ (2023) Utilization of waste materials in the stabilization of expansive pavement subgrade: an extensive review. Constr Build Mater 398:132435. https://doi.org/10.1016/j.conbuildmat.2023.132435
Tarinejad R, Moharami F, Fadaei MA, Sanaie M, Safikhanlou H (2022) Experimental investigation of soft soil stabilization using copper slag-based geopolymer. Available at SSRN 4002323
Thaarrini J, Dhivya S (2016) Comparative study on the production cost of geopolymer and conventional concretes. Int J Civil Eng Res 7(2):117–124
Vasanthi R, Anuradha K, Velmanirajan BR (2019) Experimental study on optimum usage of copper slag and quarry dust for better strength using RSM. J Waste Resour Recycl 1(1):104
Wagner JF (2013) Mechanical properties of clays and clay minerals. Developments in clay science, vol 5. Elsevier, Amsterdam, pp 347–381
Wang J, Fan Y, Xiong X, Zhao F (2023) Stabilization of shield muck treated with calcium carbide slag-fly ash. Buildings 13(7):1707. https://doi.org/10.3390/buildings13071707
Wei J, Wei J, Huang Q, Zainal Abidin SMIBS, Zou Z (2023) Mechanism and engineering characteristics of expansive soil reinforced by industrial solid waste: a review. Buildings 13(4):1001. https://doi.org/10.3390/buildings13041001
Zhang D, Zhang Y, Cao Z, Cheng T (2020) Optimization of roots and copper slag to reinforce soft soil using response surface method. J Renew Mater 8(11):1391
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Jangid, A.K., Grover, K.S. Experimental investigation of mechanical properties of problematic expansive soil using copper slag and its statistical validation. Multiscale and Multidiscip. Model. Exp. and Des. (2023). https://doi.org/10.1007/s41939-023-00316-z
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DOI: https://doi.org/10.1007/s41939-023-00316-z