Related references
Note: Only part of the references are listed.Comparative study of hazelnut-shell biomass ash and metakaolin to improve the performance of alkali-activated concrete: A sustainable greener alternative
Umit Yurt et al.
CONSTRUCTION AND BUILDING MATERIALS (2022)
Novel one-part alkali-activated binder produced with coffee husk ash
Felipe Silva Lima et al.
MATERIALS LETTERS (2022)
Identification and characterization of faujasite zeolite phase in alkali activated class F fly ash
Jihane Moudar et al.
MATERIALS TODAY-PROCEEDINGS (2022)
Alkali-activated and geopolymer materials developed using innovative manufacturing techniques: A critical review
H. S. Gokce et al.
CONSTRUCTION AND BUILDING MATERIALS (2021)
Ternary Mixes of Self-Compacting Concrete with Fly Ash and Municipal Solid Waste Incinerator Bottom Ash
B. Simoes et al.
APPLIED SCIENCES-BASEL (2021)
Fresh and hardened properties of geopolymer binder using ground high magnesium ferronickel slag with fly ash
Jhutan Chandra Kuri et al.
CONSTRUCTION AND BUILDING MATERIALS (2021)
A mix design method of fly ash geopolymer concrete based on factors analysis
Chenchen Luan et al.
CONSTRUCTION AND BUILDING MATERIALS (2021)
Mortars with alkali-activated municipal solid waste incinerator bottom ash and fine recycled aggregates
S. Casanova et al.
JOURNAL OF CLEANER PRODUCTION (2021)
Concrete Strengthening by Introducing Polymer-Based Additives into the Cement Matrix-A Mini Review
Weronika Kujawa et al.
MATERIALS (2021)
Effects of Fluorogypsum and Flue-Gas Desulfurization Gypsum on the Hydration and Hardened Properties of Alkali Slag Cement
Cheng Wang et al.
CRYSTALS (2021)
Alkali activation of bottom ash from municipal solid waste incineration: Optimization of NaOH- and Na 2SiO3-based activators
R. Carvalho et al.
JOURNAL OF CLEANER PRODUCTION (2021)
Effective and sustainable use of municipal solid waste incineration bottom ash in concrete regarding strength and durability
N. M. Alderete et al.
RESOURCES CONSERVATION AND RECYCLING (2021)
Alkali-Activated Binders Using Bottom Ash from Waste-to-Energy Plants and Aluminium Recycling Waste
Alex Maldonado-Alameda et al.
APPLIED SCIENCES-BASEL (2021)
Influence of the geopolymer formulation on the endogeneous shrinkage
Julien Archez et al.
CONSTRUCTION AND BUILDING MATERIALS (2021)
Treatment of municipal solid waste incineration fly ash: State-of-the-art technologies and future perspectives
Yuying Zhang et al.
JOURNAL OF HAZARDOUS MATERIALS (2021)
Essential for what? A global social reproduction view on the re-organisation of work during the COVID-19 pandemic
Sara Stevano et al.
CANADIAN JOURNAL OF DEVELOPMENT STUDIES-REVUE CANADIENNE D ETUDES DU DEVELOPPEMENT (2021)
Emerging trends in municipal solid waste incineration ashes research: a bibliometric analysis from 1994 to 2018
Syieluing Wong et al.
ENVIRONMENTAL SCIENCE AND POLLUTION RESEARCH (2020)
Recycling municipal solid waste incineration slag and fly ash as precursors in low-range alkaline cements
Nuno Cristelo et al.
WASTE MANAGEMENT (2020)
Use of pretreatment to prevent expansion and foaming in high-performance MSWI bottom ash alkali-activated mortars
Guodong Huang et al.
CONSTRUCTION AND BUILDING MATERIALS (2020)
Influence of NaOH content on the alkali conversion mechanism in MSWI bottom ash alkali-activated mortars
Guodong Huang et al.
CONSTRUCTION AND BUILDING MATERIALS (2020)
Dust filter of secondary aluminium industry as raw material of geopolymer foams
D. Eliche-Quesada et al.
JOURNAL OF BUILDING ENGINEERING (2020)
Properties of fresh and hardened fly ash/slag based geopolymer concrete: A review
Peng Zhang et al.
JOURNAL OF CLEANER PRODUCTION (2020)
Opportunities and challenges associated with using municipal waste incineration ash as a raw ingredient in cement production - a review
Kyle A. Clavier et al.
RESOURCES CONSERVATION AND RECYCLING (2020)
Fresh, strength and microstructure properties of geopolymer concrete incorporating lime and silica fume as replacement of fly ash
Shaswat Kumar Das et al.
JOURNAL OF BUILDING ENGINEERING (2020)
Pre-treatment and utilisation of municipal solid waste incineration bottom ashes towards a circular economy
Aneeta Mary Joseph et al.
CONSTRUCTION AND BUILDING MATERIALS (2020)
Evolution of zeolite crystals in geopolymer-supported zeolites: effects of composition of starting materials
Hammad R. Khalid et al.
MATERIALS LETTERS (2019)
Effects of combined usage of GGBS and fly ash on workability and mechanical properties of alkali activated geopolymer concrete with recycled aggregate
Jianhe Xie et al.
COMPOSITES PART B-ENGINEERING (2019)
Use of slaked lime and Portland cement to improve the resistance of MSWI bottom ash-GBFS geopolymer concrete against carbonation
Guodong Huang et al.
CONSTRUCTION AND BUILDING MATERIALS (2018)
Metakaolin-based geopolymer mortars with different alkaline activators (Na+ and K+)
Thais da Silva Rocha et al.
CONSTRUCTION AND BUILDING MATERIALS (2018)
Use of municipal solid waste incinerator (MSWI) bottom ash in high calcium fly ash geopolymer matrix
Ampol Wongsa et al.
JOURNAL OF CLEANER PRODUCTION (2017)
Municipal incinerated bottom ash use as a cement component in concrete
Ciaran J. Lynn et al.
MAGAZINE OF CONCRETE RESEARCH (2017)
Influence of fly ash on the pore structure and shrinkage characteristics of metakaolin-based geopolymer pastes and mortars
Tao Yang et al.
CONSTRUCTION AND BUILDING MATERIALS (2017)
Effect of Na2O content, SiO2/Na2O molar ratio, and curing conditions on the compressive strength of FA-based geopolymer
Young-Keun Cho et al.
CONSTRUCTION AND BUILDING MATERIALS (2017)
Effect of high dosage lignosulphonate and naphthalene sulphonate based plasticizer usage on micro concrete properties
Ilker Bekir Topcu et al.
CONSTRUCTION AND BUILDING MATERIALS (2016)
Geoenvironmental weathering/deterioration of landfilled MSWI-BA glass
Yunmei Wei et al.
JOURNAL OF HAZARDOUS MATERIALS (2014)
Natural carbonation of aged alkali-activated slag concretes
Susan A. Bernal et al.
MATERIALS AND STRUCTURES (2014)
Compatibility between superplasticizer admixtures and cements with mineral additions
Olga Burgos-Montes et al.
CONSTRUCTION AND BUILDING MATERIALS (2012)
Ambient Temperature Drying Shrinkage and Cracking in Metakaolin-Based Geopolymers
Carsten Kuenzel et al.
JOURNAL OF THE AMERICAN CERAMIC SOCIETY (2012)
Properties of municipal solid waste incineration ashes with respect to their separation temperature
Martin Keppert et al.
WASTE MANAGEMENT & RESEARCH (2012)
Influence of activator type on hydration kinetics, hydrate assemblage and microstructural development of alkali activated blast-furnace slags
M. Ben Haha et al.
CEMENT AND CONCRETE RESEARCH (2011)
The effect of activator concentration on the residual strength of alkali-activated fly ash pastes subjected to thermal load
Alaa M. Rashad et al.
CONSTRUCTION AND BUILDING MATERIALS (2011)
Generation of hydrogen from aluminum and water - Effect of metal oxide nanocrystals and water quality
Hong-Wen Wang et al.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY (2011)
The role of particle technology in developing sustainable construction materials
John L. Provis et al.
ADVANCED POWDER TECHNOLOGY (2010)
Application of activated aluminum powder for generation of hydrogen from water
Valery Rosenband et al.
INTERNATIONAL JOURNAL OF HYDROGEN ENERGY (2010)
Understanding the chemical and mineralogical properties of the inorganic portion of MSWI bottom ash
A. P. Bayuseno et al.
WASTE MANAGEMENT (2010)
Geopolymer technology:: the current state of the art
P. Duxson et al.
JOURNAL OF MATERIALS SCIENCE (2007)
The effect of alkali and Si/Al ratio on the development of mechanical properties of metakaolin-based geopolymers
P. Duxson et al.
COLLOIDS AND SURFACES A-PHYSICOCHEMICAL AND ENGINEERING ASPECTS (2007)
Life cycle assessment of disposal of residues from municipal solid waste incineration:: Recycling of bottom a sh in road construction or landfilling in Denmark evaluated in the ROAD-RES model
H. Birgisdottir et al.
WASTE MANAGEMENT (2007)
Mechanical and durable behaviour of alkaline cement mortars reinforced with polypropylene fibres
F Puertas et al.
CEMENT AND CONCRETE RESEARCH (2003)