# | Title | Journal | Year | Citations |
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1 | Influence of bacteria on the compressive strength, water absorption and rapid chloride permeability of fly ash concrete | Construction and Building Materials | 2012 | 300 |
2 | Environmental impact assessment of fly ash and silica fume based geopolymer concrete | Journal of Cleaner Production | 2020 | 281 |
3 | Use of different forms of waste plastic in concrete – a review | Journal of Cleaner Production | 2016 | 278 |
4 | Properties of self-compacting concrete containing class F fly ash | Materials & Design | 2011 | 220 |
5 | Recycling of landfill wastes (tyres, plastics and glass) in construction – A review on global waste generation, performance, application and future opportunities | Resources, Conservation and Recycling | 2021 | 216 |
6 | Strength properties and micro-structural properties of concrete containing coal bottom ash as partial replacement of fine aggregate | Construction and Building Materials | 2014 | 193 |
7 | Effect of coal bottom ash as partial replacement of sand on properties of concrete | Resources, Conservation and Recycling | 2013 | 191 |
8 | Supplementary Cementing Materials | Engineering Materials | 2011 | 185 |
9 | Effect of coal bottom ash as partial replacement of sand on workability and strength properties of concrete | Journal of Cleaner Production | 2016 | 158 |
10 | Properties of concrete containing high volumes of coal bottom ash as fine aggregate | Journal of Cleaner Production | 2015 | 152 |
11 | Use of iron and steel industry by-product (GGBS) in cement paste and mortar | Resources, Conservation and Recycling | 2012 | 140 |
12 | Prediction of Compressive Strength of Concrete Using Artificial Neural Network and Genetic Programming | Advances in Materials Science and Engineering | 2016 | 131 |
13 | Compressive strength, water absorption, sorptivity, abrasion resistance and permeability of self-compacting concrete containing coal bottom ash | Construction and Building Materials | 2013 | 125 |
14 | Microbial healing of cracks in concrete: a review | Journal of Industrial Microbiology and Biotechnology | 2017 | 122 |
15 | Accelerated carbonation curing of cement mortars containing cement kiln dust: An effective way of CO2 sequestration and carbon footprint reduction | Journal of Cleaner Production | 2018 | 119 |
16 | Waste foundry sand and its leachate characteristics | Resources, Conservation and Recycling | 2010 | 115 |
17 | Utilization of Industrial By-products in Concrete | Procedia Engineering | 2014 | 111 |
18 | Permeability of high-performance concrete subjected to elevated temperature (600°C) | Construction and Building Materials | 2009 | 108 |
19 | Compressive strength, drying shrinkage and chemical resistance of concrete incorporating coal bottom ash as partial or total replacement of sand | Construction and Building Materials | 2014 | 104 |
20 | Use of cement kiln dust in cement concrete and its leachate characteristics | Resources, Conservation and Recycling | 2012 | 100 |
21 | Permeation properties of concrete made with fly ash and silica fume: Influence of ureolytic bacteria | Construction and Building Materials | 2013 | 97 |
22 | Utilization of waste materials and by-products in producing controlled low-strength materials | Resources, Conservation and Recycling | 2009 | 92 |
23 | Use of municipal solid waste ash in concrete | Resources, Conservation and Recycling | 2010 | 88 |
24 | Influence of high temperature on the properties of concretes made with industrial by-products as fine aggregate replacement | Construction and Building Materials | 2011 | 88 |
25 | Pristine and amino functionalized carbon nanotubes reinforced glass fiber epoxy composites | Composites Part A: Applied Science and Manufacturing | 2015 | 83 |
26 | Utilization of coal combustion by-products in sustainable construction materials | Resources, Conservation and Recycling | 2010 | 78 |
27 | Comparative investigation on the influence of spent foundry sand as partial replacement of fine aggregates on the properties of two grades of concrete | Construction and Building Materials | 2015 | 76 |
28 | Effects of elevated temperatures on properties of self-compacting-concrete containing fly ash and spent foundry sand | Construction and Building Materials | 2012 | 74 |
29 | Abrasion resistance and mechanical properties of high-volume fly ash concrete | Materials and Structures/Materiaux Et Constructions | 2010 | 61 |
30 | Influence of various parameters on strength and absorption properties of fly ash based geopolymer concrete designed by Taguchi method | Construction and Building Materials | 2017 | 61 |
31 | Behavior of RC exterior beam column joint retrofitted using UHP-HFRC | Construction and Building Materials | 2019 | 61 |
32 | Strength and permeation properties of self-compacting concrete containing fly ash and hooked steel fibres | Construction and Building Materials | 2016 | 59 |
33 | Utilization (recycling) of iron and steel industry by-product (GGBS) in concrete: strength and durability properties | Journal of Material Cycles and Waste Management | 2014 | 58 |
34 | Influence of nutrient components of media on structural properties of concrete during biocementation | Construction and Building Materials | 2018 | 58 |
35 | Utilization of carbon dioxide as an alternative to urea in biocementation | Construction and Building Materials | 2016 | 56 |
36 | Model for mix design of brick aggregate concrete based on neural network modelling | Construction and Building Materials | 2017 | 52 |
37 | Impact of seismic factors on landslide susceptibility zonation: a case study in part of Indian Himalayas | Landslides | 2010 | 51 |
38 | Comparison of Machine Learning Techniques for the Prediction of Compressive Strength of Concrete | Advances in Civil Engineering | 2018 | 51 |
39 | Effect of nano silica and coir fiber on compressive strength and abrasion resistance of Concrete | Construction and Building Materials | 2019 | 51 |
40 | Effect of volcanic ash on the properties of cement paste and mortar | Resources, Conservation and Recycling | 2011 | 49 |
41 | Strength properties and micro-structural analysis of self-compacting concrete made with iron slag as partial replacement of fine aggregates | Construction and Building Materials | 2016 | 48 |
42 | Predicting river water quality index using data mining techniques | Environmental Earth Sciences | 2017 | 48 |
43 | Thermo-mechanical characteristics of concrete at elevated temperatures up to 310°C | Nuclear Engineering and Design | 2009 | 47 |
44 | Properties of hydrophobised lightweight mortars with expanded cork | Construction and Building Materials | 2017 | 46 |
45 | Effect of metakaolin and foundry sand on the near surface characteristics of concrete | Construction and Building Materials | 2011 | 45 |
46 | Protection of concrete structures under sulfate environments by using calcifying bacteria | Construction and Building Materials | 2019 | 45 |
47 | A comprehensive review on effects of mineral admixtures and fibers on engineering properties of ultra-high-performance concrete | Journal of Building Engineering | 2022 | 43 |
48 | Acoustic emission vis-à-vis electrochemical techniques for corrosion monitoring of reinforced concrete element | Construction and Building Materials | 2014 | 42 |
49 | Strength properties and microstructural analysis of self-compacting concrete incorporating waste foundry sand | Construction and Building Materials | 2019 | 42 |
50 | Properties of concrete containing fungal treated waste foundry sand | Construction and Building Materials | 2012 | 41 |