Sustainable reuse of dredged sediments as pavement materials by cement and fly ash stabilization

AASHTO (1993) Guide for design of pavement structures. AASHTO, Washington, DC

AASHTO (2012) Standard method of test for determining the resilient modulus of soils and aggregate materials. AASHTO, T 307, Washington, DC

Abu-farsakh M, Dhakal S, Chen Q (2015) Laboratory characterization of cementitiously treated/stabilized very weak subgrade soil under cyclic loading. Soils Found 55(3):504–516

Agapitus AA (2014) Enhancing durability of quarry fines modified black cotton soil subgrade with cement kiln dust stabilization. Transport Geotech 1:55–61

Ahmed A (2015) Compressive strength and microstructure of soft clay soil stabilized with recycled bassanite. Appl Clay Sci 104:27–35

Al-Homidy AA, Dahim MH, Abd El Aal AK (2017) Improvement of geotechnical properties of sabkha soil utilizing cement kiln dust. J Rock Mech Geotech Eng 9(4):749–760

Ardah A, Chen Q, Abu-farsakh M (2017) Transportation geotechnics evaluating the performance of very weak subgrade soils treated / stabilized with cementitious materials for sustainable pavements. Transp Geotech 11:107–119

Arora S, Aydilek AH (2005) Class F fly-ash-amended soils as highway base materials. J Mater Civ Eng 17(6):640–649

ASTM (2012) Standard specification for coal Fly ash and raw or calcined natural pozzolan for use in concrete. Standard C 618. ASTM, west Conshohocken, USA

ASTM (2015) Standard test methods for laboratory compaction characteristics of soil using modified effort. Standard D 1557. ASTM, west Conshohocken, USA

ASTM (2016a) Standard test method for unconfined compressive strength of cohesive soil. Standard D 2166/D 2166M. ASTM, west Conshohocken, USA

ASTM (2016b) Standard Test Method for California Bearing Ratio (CBR) of Laboratory-Compacted Soil. Standard D 1883. ASTM, west Conshohocken, USA

Austroads (2017) Guide to pavement technology part 2: pavement structural design. Austroads, Sydney

Bilondi MP, Toufigh MM, Toufigh V (2018) Experimental investigation of using a recycled glass powder-based geopolymer to improve the mechanical behavior of clay soils. Constr Build Mater 170:302–313

COE (U.S. Army Corps of Engineers) (2004) Soil stabilization for pavements. TM 5–822-14/AFJMAN 32/1019. http://www.wbdg.org/ccb/DOD/UFC/ufc_3_250_11.pdf

Dermatas D, Meng X (2003) Utilization of fly ash for stabilization / solidification of heavy metal contaminated soils. Eng Geol 70:377–394

Dubois V, Zentar R, Abriak NE, Grégoire P (2011) Fine sediments as a granular source for civil engineering. Eur J Environ Civ Eng 15:137–166

Garber NJ, Hoel LA (2015) Traffic and highway engineering, 5th edn. Cengage Learning, Stamford

Güllü H (2014) Factorial experimental approach for effective dosage rate of stabilizer: application for fine-grained soil treated with bottom ash. Soils Found 54(3):462–477

Güllü H, Canakci H, Al Zangana IF (2017) Use of cement based grout with glass powder for deep mixing. Constr Build Mater 137:12–20

Gupta A, Arora VK, Biswas S (2017) Contaminated dredged soil stabilization using cement and bottom ash for use as highway subgrade fill. Int J Geo-Engineer 8:20

Horpibulsuk S, Rachan R, Raksachon Y (2009) Role of fly ash on strength and microstructure development in blended cement stabilized silty clay. Soils Found 49(1):85–98

Horpibulsuk S, Rachan R, Chinkulkijniwat A, Raksachon Y (2010) Analysis of strength development in cement-stabilized silty clay from microstructural considerations. Constr Build Mater 24(10):2011–2021

Horpibulsuk S, Rachan R, Suddeepong A (2011) Assessment of strength development in blended cement admixed Bangkok clay. Constr Build Mater 25(4):1521–1531

Horpibulsuk S, Phojan W, Suddeepong A, Chinkulkijniwat A, Liu MD (2012) Strength development in blended cement admixed saline clay. Appl Clay Sci 55:44–52

Jamsawang P, Poorahong H, Yoobanpot N, Songpiriyakij S, Jongpradist P (2017) Improvement of soft clay with cement and bagasse ash waste. Constr Build Mater 154:61–71

Jaritngam S, Swasdi S, Tonnayopas D, Thongchim P (2008) Improvement for subsoil by cement column - a case study in Thailand. Proceedings of the 13th International Conference of Hong Kong Society for Transportation Studies of two-day duration (Hong Kong, 13th – 15th December 2008)

Jiang NJ, Du YJ, Liu SY, Wei ML, Horpibulsuk S, Arulrajah A (2015) Multi-scale laboratory evaluation of the physical, mechanical, and microstructural properties of soft highway subgrade soil stabilized with calcium carbide residue. Can Geotech J 52:1–11

Jongpradist P, Jumlongrach N, Youwai S, Chucheepsakul S (2010) Influence of fly ash on unconfined compressive strength of cement-admixed clay at high water content. J Mater Civ Eng 22:49–58

Kamali S, Bernard F, Abriak NE (2008) Marine dredged sediments as new materials resource for road construction. Waste Manag 28:918–928

Kampala A, Horpibulsuk S (2013) Engineering properties of silty clay stabilized with calcium carbide residue. J Mater Civ Eng 25(5):632–644

Kampala A, Horpibulsuk S, Prongmanee N, Chinkulkijniwat A (2014) Influence of wet-dry cycles on compressive strength of calcium carbide residue–fly ash stabilized clay. J Mater Civ Eng 26(4):633–643

Kang X, Kang G-C, Chang K-T, Ge L (2015) Chemically stabilized soft clays for road-base construction. J Mater Civ Eng 27(7):04014199

Kogbara RB, Al-Tabbaa A, Yi Y, Stegemann JA (2013) Cement-fly ash stabilization / solidification of contaminated soil: performance properties and initiation of operating envelopes. Appl Geochem 33:64–75

Li J, Poon CS (2017) Innovative solidification/stabilization of lead contaminated soil using incineration sewage sludge ash. Chemosphere 173:143–152

Mohammadinia A, Arulrajah A, Sanjayan J, Disfani MM, Bo MW, Darmawan S (2015) Laboratory evaluation of the use of cement-treated construction and demolition materials in pavement base and subbase applications. J Mater Civ Eng 27:04014186-1-10

Osinubi KJ, Oyelakin MA, Eberemu AO (2011) Improvement of black cotton soil with ordinary Portland cement - locust bean waste ash blend. EJGE 16:619–627

Razouki SS, Ibrahim AN (2017) Improving the resilient modulus of a gypsum sand roadbed soil by increased compaction. Int J Pavemet Eng 20(4):432–438

Razouki SS, Kuttah DK (2004) Effect of soaking period and surcharge load on resilient modulus and California bearing ratio of gypsiferous soils. Quart J Engineer Geol Hydrogeol 37:155–164

Scanferla P, Ferrari G, Pellay R, Ghirardini AV, Zanetto G, Libralato G (2009) An innovative stabilization/solidification treatment for contaminated soil remediation: demonstration project results. J Soils Sediments 9:229–236

Shaheen SM, Hooda PS, Tsadilas CD (2014) Opportunities and challenges in the use of coal fly ash for soil improvements – a review. J Environ Manag 145:249–267

Shon C-S, Saylak D, Mishra SK (2010) Combined use of calcium chloride and fly ash in road base stabilization. Transp Res Rec J Transp Res Board 2186(1):120–129

Silitonga E, Levacher D, Mezazigh S (2009) Effects of the use of fly ash as a binder on the mechanical behaviour of treated dredged sediments. Environ Technol 30(8):799–807

Solanki P, Zaman MM, Dean J (2011) Resilient modulus of clay subgrades stabilized with lime, class C fly ash, and cement kiln dust for pavement design. Transp Res Rec J Transp Res Board 2186(1):101–110

Suksiripattanapong C, Horpibulsuk S, Boongrasan S, Udomchai A (2015) Unit weight, strength and microstructure of a water treatment sludge–fly ash lightweight cellular geopolymer. Constr Build Mater 94:807–816

Tang CS, Cui YJ, Shi B, Tang AM, Liu C (2011) Desiccation and cracking behaviour of clay layer from slurry state under wetting-drying cycles. Geoderma 166:111–118

Tastan EO, Edil TB, Benson CH, Aydilek AH (2011) Stabilization of organic soils with fly ash. J Geotech Geoenviron Eng 137(9):819–833

Tebaldi G, Orazi M, Orazi US (2016) Effect of freeze–thaw cycles on mechanical behavior of lime-stabilized soil. J Mater Civ Eng 06016002

Tomasevic DD, Dalmacija MB, Prica DM, Dalmacija BD, Kerkez DV, Becelic-Tomin MR, Roncevic SD (2013) Use of fly ash for remediation of metals polluted sediment – green remediation. Chemosphere 92:1490–1497

Tongwei Z, Xibing Y, Yongfeng D, Dingwen Z, Songyu L (2014) Mechanical behaviour and micro-structure of cement-stabilised marine clay with a metakaolin agent. Constr Build Mater 73:51–57

Tripathy S, Rao SSK (2009) Cyclic swell-shrink behavior of a compacted expansive soil. Geotech Geol Eng J 27(1):89–103

Voottipruex P, Jamsawang P (2014) Characteristics of expansive soils improved with cement and fly ash in Northern Thailand. Geomech Eng 6:437–453

Wang D, Edine N, Zentar R (2013) Strength and deformation properties of Dunkirk marine sediments solidified with cement, lime and fly ash. Eng Geol 166:90–99

Wang L, Tsang DCW, Poon C (2015) Green remediation and recycling of contaminated sediment by waste-incorporated stabilization / solidification. Chemosphere 122:257–264

Wang D, Zentar R, Abriak NE (2018) Durability and swelling of solidified/stabilized dredged marine soils with class-F fly ash, cement, and lime. J Mater Civ Eng 30(3):04018013

Wen H, Warner J, Edil T, Wang G (2010) Laboratory comparison of crushed aggregate and recycled pavement material with and without high carbon fly ash. Geotech Geol Eng 28:405–411

Yilmaz F, Fidan D (2018) Influence of freeze-thaw on strength of clayey soil stabilized with lime and perlite. Geomech Eng 14(3):301–306

Yin CY, Mahmud HB, Shaaban MG (2006) Stabilization/solidification of lead-contaminated soil using cement and rice husk ash. J Hazard Mat 137:1758–1764

Yoobanpot N, Jamsawang P, Horpibulsuk S (2017) Strength behavior and microstructural characteristics of soft clay stabilized with cement kiln dust and fly ash residue. Appl Clay Sci 141:146–156