prof. dr. Nele De Belie
work address
Technologiepark Zwijnaarde 904
9052 Zwijnaarde
9052 Zwijnaarde
ORCID iD

bio (via ORCID)
See: http://www.ugent.be/ea/structural-engineering/en/research/magnel/staff/biography/debelie.htm
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- 2018
- Applying a biodeposition layer to increase the bond of a repair mortar on a mortar substrate (
- The use of municipal solid waste incineration ash in various building materials : a Belgian point of view (
- Testing superabsorbent polymer (SAP) sorption properties prior to implementation in concrete: results of a RILEM Round-Robin Test (
- Valorisation on municipal solid waste incineration residues in concrete products (
- X-ray radiography to visualize the rebar-cementitious matrix interface and judge the delay in corrosion through self-repair by encapsulated polyurethane (
- Recommendation of RILEM TC 238-SCM: determination of the degree of reaction of siliceous fly ash and slag in hydrated cement paste by the selective dissolution method (
- 2017
- Determination of strength and debonding energy of a glass-concrete interface for encapsulation-based self-healing concrete (
- A novel design of autonomously healed concrete : towards a vascular healing network (
- Quantification of the service life extension and environmental benefit of chloride exposed self-healing concrete (
- Influence of the curing period of encapsulated polyurethane precursor on the capillary water absorption of cracked mortar with selfhealing properties (
-
XIV DBMC 14th International Conference on Durability of Building Materials and Components
Geert De Schutter UGent, Nele De Belie UGent, Arnold Janssens UGent and Nathan Van Den Bossche UGent (2017) In RILEM Proceedings PRO 107. Mark
- Development of amine-based pH-responsive superabsorbent polymers for mortar applications (
- Characterization of supplementary cementitious materials by thermal analysis (
- Microbial carbonate precipitation for the improvement of quality of recycled aggregates (
- Influence of intensive vacuum mixing and heat treatment on compressive strength and microstructure of reactive powder concrete incorporating secondary copper slag as supplementary cementitious material (
- Improving the quality of various types of recycled aggregates by biodesposition (
- Effect of supplementary cementitious materials on capillary sorption : relation with drying rate and testing time (
- On the quantitative thermogravimetric analysis of calcite content in hydrated cementitious systems (
- Freeze-thaw durability of recycled concrete from construction and demolition wastes (
- Crack mitigation in concrete : superabsorbent polymers as key to success? (
- Stability of Pluronic (R) F127 bismethacrylate hydrogels: Reality or utopia? (
- Sulfates in completely recyclable concrete and the effect of CaSO4 on the clinker mineralogy (
- Recommendation of RILEM TC 246-TDC: test methods to determine durability of concrete under combined environmental actions and mechanical load (
- Quality improvement of mixed and ceramic recycled aggregates by biodeposition of calcium carbonate (
- Concrete fracture energy increase by embedding capsules with healing ability : the effect of capsules nature (
- Effect of SCMs on capillarysorption over time : relation with dryingrate and testing time (
- Acrylate-endcapped polymer precursors : effect of chemical composition on the healing efficiency of active concrete cracks (
- Use of encapsulated healing agents to limit water uptake through crackis in mortar (
- Integral procedure to assess crack filling and mechanical contribution of polymer-based healing agent in encapsulation-based self-healing concrete (
- Surface consolidation of natural stones by use of bio-agents and chemical consolidants (
- Monitoring the reduction in shrinkage cracking of mortars containing superabsorbent polymers (
- Mitigating autogenous shrinkage by means of superabsorbent polymers - effect on concrete properties (
- Self-healing approaches for the preventive repair of concrete structures : SARCOS COST Action (
- Monitoring crack movement in polymer-based self-healing concrete through digital image correlation, acoustic emission analysis and SEM in-situ loading (
- The influence of sodium and magnesium sulphate on the penetration of chlorides in mortar (
- Application of encapsulated superabsorbent polymers in cementitious materials for stimulated autogenous healing (
- Mechanical and self-healing properties of cementitious materials with pH-responsive semi-synthetic superabsorbent polymers (
- Design and testing of tubular polymeric capsules for self-healing of concrete (
- Sustainability assessment of potentially 'green' concrete types using life cycle assessment (
- Internal curing of cement pastes by superabsorbent polymers studied by means of neutron radiography (
- Self-healing of concrete cracks by the release of embedded water repellent agents and corrosion inhibitors to reduce the risk for reinforcement corrosion (
- Preliminary Investigation on the effect of cement replacement by residues from the incineration of non-hazardous waste on strength and Alkali Silica reaction (
- Calibrated quantitative thermogravimetric analysis for the determination of portlandite and calcite content in hydrated cementitious systems (
- Characterization of methacrylated alginate and acrylic monomers as versatile SAPs (
- Characterization of methacrylated polysaccharides in combination with amine-based monomers for application in mortar (
- Bacillus sphaericus LMG 22257 is physiologically suitable for self-healing concrete (
- Self-healing concrete in aggressive enironments (
- Vascular self-healing of a reinforced concrete beams under 4-point bending (
- Effect of superabsorbent polymers (SAP) on the freeze-thaw resistance of concrete: results of a RILEM interlaboratory study (
- Influence of chlorides on magnesium sulphate attack for mortars with Portland cement and slag based binders (
- Evaluation of the performance of self-healing concrete at small and large scale under laboratory conditions (
- Multiple self-repair of concrete cracks by encapsulated methyl methacrylate (
- Reducing the risk of thermal cracking in cementitious materials by means of encapsulated phase-change materials (
- Combinatory approach of methacrylated alginate and acid monomers for concrete applications (
- Service life and global warming potential of chloride exposed concrete with high volumes of fly ash (
- Comparison of different beneficiation techniques to improve utilization potential of Municipal Solid Waste Incineration fly ash concrete (
- Pore structure description of mortars containing ground granulated blast-furnace slag by mercury intrusion porosimetry and dynamic vapour sorption (
- Test methods to determine durability of concrete under combined environmental actions and mechanical load: final report of RILEM TC 246-TDC (
- Outcomes of the RILEM round robin on degree of reaction of slag and fly ash in blended cements (
- Impact of air entraining admixtures on biogenic calcium carbonate precipitation and bacterial viability (
- Fracture energy of coarse recycled aggregate concrete using the wedge splitting test method: influence of water-reducing admixtures (
- Improved model for capillary absorption in cementitious materials: Progress over the fourth root of time (
- 2016
- Bacteria-based repair and self-healing of concrete (
- Capsules with evolving brittleness to resist the preparation of self-healing concrete (
- Chloride penetration in concrete under compression or splitting tensile load representing 60-65 per cent of the ultimate load (
- Towards an adequate deicing salt scaling resistance of high-volume fly ash (HVFA) concrete and concrete with superabsorbent polymers (SAPs) (
- Superabsorbent polymers to promote and stimulate autogenous healing in cementitious materials (
- Damage detection and healing performance monitoring using embedded piezoelectric transducers in large-scale concrete structures (
- Influence of intensive vacuum mixing on the compressive strength of RPC containing secondary slag as cementitious materials (
- Repeated autogenous healing in strain-hardening cementitious composites by using superabsorbent polymers (
- Self-healing of moving cracks in concrete by means of encapsulated polymer precursors (
- Can superabsorbent polymers mitigate shrinkage in cementitious materials blended with supplementary cementitious mateirals? (
- Influence of particle size distribution of slag, limestone and fly ash on early hydration of cement assessed by isothermal calorimetry (
- Particle size distribution and specific surface area of SCM's compared through experimental techniques (
- Outcomes of the RILEM round robin on degree of reaction of slag and fly ash in composite cements (
- Evaluation of the self-healing efficiency of cracks in mortar by bioprecipitation or applications of hydrogels (
- Preventing reinforcement corrosion in cracked concrete by self-repair (
- The microstructure of capsule containing self-healing materials : a micro-computed tomography study (
- Role of the surface chemistry of the adsorbent on the initialization step of the water sorption process (
- Proposed mechanism for the formation of oxychloride crystals during sodium chloride application as a deicer salt in carbonated concrete (
- A plant based LCA of high-strength prestressed concrete elements and the assessment of a practical ecological variant (
- Enhanced crack closure performance of microbial mortar through nitrate reduction (
- Application of microorganisms in concrete: a promising sustainable strategy to improve concrete durability (
- Cross-linkable polyethers as healing/sealing agents for self-healing of cementitious materials (
- Capillary water absorption in cracked and uncracked mortar: a comparison between experimental study and finite element analysis (
- Nitrate reducing CaCO3 precipitating bacteria survive in mortar and inhibit steel corrosion (
- Non-destructive testing techniques to evaluate the healing efficiency of self-healing concrete at lab-scale (
- The cost and environmental impact of service life extening self-healing engineered materials for sustainable steel reinforced concrete (
- Bio-based self-healing concrete : from research to field application (
- Resistance to fatigue of self-healed concrete based on encapsulated polymer precursors (
- Self-healing mortar with pH-sensitive superabsorbent polymers : testing of the sealing efficiency by water flow tests (
- Chloride penetration in cracked mortar and the influence of autogenous crack healing (
- Sustainable high quality recycling of aggregates from waste-to-energy, treated in a wet bottom ash processing installation, for use in concrete products (
- Mechanical regains due to self-healing in cementitious materials: experimental measurements and micro-mechanical model (
- Setting control of completely recyclable concrete with slag and aluminate cements (
- Methods for measuring pH in concrete: a review (
- Comparison of different approaches for self-healing concrete in a large-scale lab test (
- Effect of plasticizer migration on thermal and mechanical properties of mPEG/PMMA blend for self-healing concrete application (
- Alginate biopolymers: counteracting the impact of superabsorbent polymers on mortar strength (
- Cuantificacion mineralogica de cementos mediante analisis rietveld de Drx. analisis cruzado de difractogramas experimentales y programas de refinamiento : Mineralogical quantification of cements determined by Rietveld analysis of XRD : Cross analysis of experimental pattern and software for refinement (
- Effect of sample age on the self-healing properties of cementitious mateials with superabsorbent polymers (
- Sustainability effects of including concrete cracking and healing in service life prediction for marine environments (
- Evaluation of experimental methodology to assess the sealing efficiency of bacteria-based self-healing mortar : round robin test (
- Bio-based self-healing concrete : from research to field application (
- X-ray computed microtomography to study autogenous healing of cementitious materials promoted by superabsorbent polymers (
- Simulation-aided design of tubular polymeric capsules for self-healing concrete (
- Ureolytic bacteria based self-healing concrete (
- HEALCON : self-healing concrete to create durable and sustainable concrete structures (
- Moving towards a realistic implementation of self-healing concrete based on encapsulated polymer precursors (
- Use of methacrylated alginate for self-healing concrete (
- Comparison of reaction degrees of slag and fly ash obtained by thermogravimetry and selective dissolution (
- Chloride interaction with concretes subjected to a permanent splitting tensile stress level of 65% (
- Neutron radiography based visualization and profiling of water uptake in (un)cracked and autonomously healed cementitious materials (
- Performance monitoring of large-scale autonomously healed concrete beams under four-point bending through multiple non-destructive testing methods (
- Concrete structures under impact loading : General aspects (
- Encapsulated phase-change materials as additives in cementitious materials to promote thermal comfort in concrete constructions (
- Preventing reinforcement corrosion in cracked concrete by self-repair (
- Service life estimation of cracked and healed concrete in marine environment (
- Effect of secondary copper slag as cementitious material in ultra-high performance mortar (
- Concrete with supplementary cementitious materials
- Healing of dynamic concrete cracks using acrylate-endcapped polymer precursors (
- Tube shape alterations for improved concrete pouring survivability in vascular self-healing concrete (
- Resistance to chloride penetration of self-healing concrete with encapsulated polyuretyhane (
- Influence of vacuum mixing on the carbonation resistance and microstructure of reactive powder concrete containing secondary copper slag as supplementary cementitious materials (SCM) (
- Green self-healing of cracks in concrete (
- Bio-based pH-responsive superabsorbent polymers for self-healing cracks in concrete (
- 2015
- The effects of superabsorbent polymers on the water vapour sorption properties of cementitious materials (
- The ingress of chlorides in concrete under compressive or tensile loads (
- Development and characterization of novel polymers for self-healing cementitious materials (
- Improved multiple cracking and autogenous healing in cementitious materials by means of chemically-treated natural fibres (
- The effects of superabsorbent polymers on the microstructure of cementitious materials studied by means of sorption experiments (
- Microscopic investigation of mechanical regain origins due to autogenic healing in cementitious materials (
- Durability based life cycle assessment of concrete with supplementary cementitious materials exposed to carbonation (
- Non-axenic NO3-reducing culture supersedes axenic cultures in development of microbial self-healing concrete (
- Ultrasonic wave transmission to monitor the performance of self-healing concrete based on encapsulated polymer precursors (
- Comparative study on different polymer tubes as carriers of healing agent for self-healing concrete (
- Effect of fibre type and superabsorbent polymers on the self-healing properties of strain-hardening cementitious materials (
- Determination of the degree of reaction of fly ash in blended cement pastes (
- Determination of particle size, surface area, and shape of supplementary cementitious materials by different techniques (
- From straw in bricks to modern use of microfibers in cementitious composites for improved autogenous healing: a review (
- Susceptibility of biocalcite-modified fiber cement to biodeterioration (
- Activation of pozzolanic and latent-hydraulic reactions by Alkalis in order to repair concrete cracks (
- Fines extracted from recycled concrete as alternative raw material for Portland cement clinker production (
- Effect of combined chloride-sulphate degradation and autogenous crack healing on durability of concrete elements (
- Durability performance of recycled brick concrete in a simulated farm environment (
- Self-repair of thermal cracks in concrete sandwich panels (
- pH-responsive superabsorbent polymers: a pathway to self-healing of mortar (
- Use of secondary slags in completely recyclable concrete (
- pH-sensitive superabsorbent polymers: a potential candidate material for self-healing concrete (
- Screening of bacteria and concrete compatible protection materials (
- Industrial application of biological self-healing concrete: challenges and economical feasibility (
- Self-protected nitrate reducing culture for intrinsic repair of concrete cracks (
- Global warming potential of carbonation/chloride exposed concrete with(out) consideration of the propagation period in service life assessment (
- Capsules changing in brittleness due to leaching of plasticizing agents (
- Evaluation of the self-healing effect of mortar containing polymeric healing agents (
- Microbial self-healing concrete: denitrification as an enhanced and environment-friendly apporach (
- Physical characterization methods for supplementary cementitious materials (
- Feasibility study of the use of concrete sludge as alternative raw material for Portland clinker production (
- The influence of superabsorbent polymers on the autogenous shrinkage properties of cement pastes with supplementary cementitious materials (
- Evaluation of natural colonisation of cementitious materials: effect of bioreceptivity and environmental conditions (
- The efficiency of self-healing concrete using alternative manufacturing procedures and more realistic crack patterns (
- Cement based materials and environmental approaches for a sustainable agriculture (CSA2015)
- Encapsulation of polymeric healing agents for self-healing concrete (
- Mechanical characteristics of the calcite precipitated in cracks of self-healing concrete studied by the indentation technique (
- Microbially induced CaCO3 precipitation through denitrification : an optimization study in minimal nutrient environment (
- Production of non-axenic ureolytic spores for self-healing concrete applications (
- Use of X-ray radiography and tomography to evaluate self-healing concrete (
- Utilization of copper slag as a cementitious material in reactive powder concrete (
-
Green concrete: optimization of high-strength concrete based on LCA
2015) Durability and Sustainability of Concrete Structures, Workshop Proceedings. SP-305. p.357-366 Mark(
- Smart superabsorbent polymers for self-sealing and -healing of mortar (
- Effect of chemical composition of polymeric precursors on the healing capability of cementitious materials (
- Design of polymeric capsules for self-healing concrete (
- Application of modified-alginate encapsulated carbonate producing bacteria in concrete: a promising strategy for crack self-healing (
- TC 238-SCM: hydration and microstructure of concrete with SCMs State of the art on methods to determine degree of reaction of SCMs (
- Purdocement: application of alkali-activated slag cement in Belgium in the 1950s (
- Recycled concrete in agricultural constructions: acid attack (
- Mechanical regains due to autogenic healing in cementitious materials (
- Self-healing of moving cracks in reinforced concrete based on encapsulated polymer precursors (
- Autogenous healing of cementitious materials promoted by superabsorbent polymers studied by means of X-ray computed microtomography (
- Effect of copper slag as supplementary cementitious material (SCM) in ultra high performance mortar (UHPM) (
- Sustainable cements in construction: magnesium phosphate cements to stimulate colonization of building materials (
- Bacteria based repair and self-healing of concrete (
- Real-scale testing of the efficiency of self-healing concrete (
- Analysis and visualization of water uptake in cracked and healed mortar by water absorption tests and X-ray radiography (
- Resilient denitrifiers wink at microbial self-healing concrete (
- Autonomous regeneration of concrete structures by incorporation of self-healing mechanisms (
- Impact modifier toughening polymeric capsules for self-healing concrete : a study on type and content of impact modifier (
- 2014
- A service life based global warming potential for high-volume fly ash concrete exposed to carbonation (
- Sulphates in completely recyclable concrete and their effect on the clinker mineralogy (
- The influence of different drying techniques on the water sorption properties of cement-based materials (
- Repeated autogenous healing in cementitious composites with microfibres and superabsorbent polymers (
- From lab scale to in situ applications: the ascent of a biogenic carbonate based surface treatment (
- Method development for the particle size analysis of supplementary cementitious materials (
- Ureolysis and denitrification based microbial strategies for self-healing concrete (
- The influence of carbonation on deicer scaling resistance of blast furnace slag concrete (BFSC) (
- Utility of pH-sensitive superabsorbent polymers in concrete repair (
- TiO2 coatings synthesized by liquid flame spray and low temperature sol-gel technologies on autoclaved aerated concrete for air-purifying purposes (
- Influence of active crack width control on the chloride penetration resistance and global warming potential of slabs made with fly ash + silica fume concrete (
- X-ray computed tomography proof of bacterial-based self-healing in concrete (
- Development of a low pH cementitious material to enlarge bioreceptivity (
- Comparing pH-sensitive with commercial superabsorbent polymers in cementitious materials (
- Self-healing of dynamic concrete cracks using polymer precursors as encapsulated healing agents (
- Chemical treatment of natural fibres to obtain multiple cracking and self-healing in cementitious materials (
- Microscopy and computed micro-tomography for evaluation of microbial self-healing in concrete (
- Influence of nanoparticles in UHPC by intensive (vacuum) mixing studies (
- Self-healing concrete by use of microencapsulated bacterial spores (
- Bioreceptivity evaluation of cementitious materials designed to stimulate biological growth (
- The efficiency of autonomous crack healing of mortar in chloride solutions (
- A hydration study by XRD/Rietveld analysis of cement regenerated from completely recyclable concrete (
- Resistance of concrete and mortar against combined attack of chloride and sodium sulphate (
- Ureolysis and denitrification based microbial strategies for self-healing concrete (
- Can self-repair of concrete cracks help to obtain durable concrete? (
- The efficiency of self-healing cementitious materials by means of encapsulated polyurethane in chloride containing environments (
- Resilient denitrifiers wink at microbial self-healing concrete (
- Correlating the water adsorption mechanism at low relative pressures of activated carbons with cements (
- Self-healing cementitious materials by the combination of microfibres and superabsorbent polymers (
- Life cycle assessment of completely recyclable concrete (
- Effect of high amounts of superabsorbent polymers and additional water on the workability, microstructure and strength of mortars with a water-to-cement ratio of 0.50 (
- How to seal and heal cracks in cementitious materials by using superabsorbent polymers (
- Application of hydrogel encapsulated carbonate precipitating bacteria for approaching a realistic self-healing in concrete (
- The hydration of cement regenerated from Completely Recyclable Concrete (
- Effect of water availability on microbial self-healing of concrete (
- Influence of the surface oxygen content of the material on the specific interactions taking place at the first stages of water sorption (
- 2013
- Use of neutron radiography and tomography to visualize the autonomous crack sealing efficiency in cementitious materials (
- Microbial interactions with mineral building materials (
- SHE: the Flemish program on engineered self-healing materials (
- Broadening the water vapour absorption modeling of activated carbons towards cementitious materials (
- Resistance of cracked concrete to chloride attack (
- Microfibres and hydrogels to promote autogenous healing in cementitious materials (
- Investigation of the fracture cracking behavior of self-healing systems by use of optical and acoustic experimental methods (
- Experimental techniques used to verify healing (
-
ICSHM2013 Fourth international conference on self-healing materials
Nele De Belie UGent, Sybrand van der Zwaag, Elke Gruyaert, Kim Van Tittelboom UGent and Brenda Debbaut UGent (2013) Mark
- Test methods for resistance of concrete to sulfate attack : a critical review (
- Testing for degradation by inorganic acids (
- The effect of chloride and sulfate on Completely Recyclable Concrete (
- Monitoring of autonomous healing process of concrete by acoustic emission and digital image correlation (
- Carbonation of slag concrete: effect of the cement replacement level and curing on the carbonation coefficient: effect of carbonation on the pore structure (
- Enhanced self-healing capacity in cementitious materials by use of encapsulated carbonate precipitating bacteria: from proof-of-concept to reality (
- The influence of superabsorbent polymers on the microstructure and permeability of cementitious materials (
- Feasibility study on the use of cellular concrete as alternative raw material for Portland clinker production (
- Self-healing of thermal cracks in sandwich panels (
- Influence of temperature on the effectiveness of a biogenic carbonate surface treatment for limestone conservation (
- Self-healing in cementitious materials-A review (
- The regeneration of cement out of Completely Recyclable Concrete: clinker production evaluation (
- Influence of crack width limitation on the chloride penetration resistance and global warming potential of concrete slabs (
- Resistance of cracked concrete healed by means of polyurethane against chloride penetration (
- Titanium dioxide based strategies to prevent algal fouling on cementitious materials (
- Application of pH-sensitive hydrogels for concrete applications (
- Influence of raw material fineness on clinker produced from Completely Recyclable Concrete (
- Influence of air entraining agents on deicing salt scaling resistance and transport properties of high-volume fly ash concrete (