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| "id","name","citation","url","source_key" | |
| "PAPER_001","1-s2.0-S095006181732278X-main.pdf","M. Li, H. Hao, Y. Shi, et al., Specimen shape and size effects on the concrete compressive strength under static and dynamic tests, Construction and Building Materials (2018).","https://www.sciencedirect.com/science/article/pii/S095006181732278X","1-s2.0-s095006181732278x-main.pdf" | |
| "PAPER_002","1-s2.0-S0950061820330786-main.pdf","Y. Zhang, H. Li, A. Abdelhady, et al., Effects of specimen shape and size on the permeability and mechanical properties of porous concrete, Construction and Building Materials (2021).","https://www.sciencedirect.com/science/article/pii/S0950061820330786","1-s2.0-s0950061820330786-main.pdf" | |
| "PAPER_003","1-s2.0-S1359836816316882-main.pdf","J. Fládr, P. Bílý, Specimen size effect on compressive and flexural strength of high-strength fibre-reinforced concrete containing coarse aggregate, Composites Part B: Engineering (2018).","https://www.sciencedirect.com/science/article/pii/S1359836816316882","1-s2.0-s1359836816316882-main.pdf" | |
| "PAPER_004","1-s2.0-S2090447920301593-main.pdf","A. Talaat, A. Emad, A. Tarek, et al., Factors affecting the results of concrete compression testing: A review, Ain Shams Engineering Journal (2021).","https://www.sciencedirect.com/science/article/pii/S2090447920301593","1-s2.0-s2090447920301593-main.pdf" | |
| "PAPER_005","2011-EffectofSpecimenSizeonStaticStrengthandDIFofHSCfromSHPBTest.pdf",", Haushaltsbegleitgesetz 2011 (HBeglG 2011), Bundesgesetzblatt (2010).","https://doi.org/10.7328/bgbl_2010_0000487_h63","2011-effectofspecimensizeonstaticstrengthanddifofhscfromshpbtest.pdf" | |
| "PAPER_006","Capacitance-based stress self-sensing in cement paste without requiring any admixture.pdf","D. Chung, Y. Wang, Capacitance-based stress self-sensing in cement paste without requiring any admixture, Cement and Concrete Composites (2018).","https://doi.org/10.1016/j.cemconcomp.2018.09.017","capacitance-based stress self-sensing in cement paste without requiring any admixture.pdf" | |
| "PAPER_007","Capacitive compressive stress self-sensing behavior of cement mortar and its dependence on the thickness.pdf","M. Ozturk, Capacitive compressive stress self-sensing behavior of cement mortar and its dependence on the thickness, Physica Scripta (2024).","https://doi.org/10.1088/1402-4896/ad1f1a","capacitive compressive stress self-sensing behavior of cement mortar and its dependence on the thickness.pdf" | |
| "PAPER_008","Carbon fiber reinforced cement improved by using silane-treated carbon fibers.pdf","Y. Xu, D. Chung, Carbon fiber reinforced cement improved by using silane-treated carbon fibers, Cement and Concrete Research (1999).","https://doi.org/10.1016/s0008-8846(99)00015-0","carbon fiber reinforced cement improved by using silane-treated carbon fibers.pdf" | |
| "PAPER_009","Development of self-sensing ultra-high-performance concrete using hybrid carbon black and carbon nanofibers.pdf","W. Li, Y. Guo, X. Zhang, W. Dong, X. Li, et al., Development of self-sensing ultra-high-performance concrete using hybrid carbon black and carbon nanofibers, Cement and Concrete Composites (2024).","https://doi.org/10.1016/j.cemconcomp.2024.105466","development of self-sensing ultra-high-performance concrete using hybrid carbon black and carbon nanofibers.pdf" | |
| "PAPER_010","Development of sensing concrete Principles, properties and its applications.pdf","Development Of Sensing Concrete Principles, Properties And Its Applications","https://doi.org/10.1063/1.5128242","development of sensing concrete principles, properties and its applications.pdf" | |
| "PAPER_011","EVALUA~1.PDF","H. Zhu, H. Zhou, H. Gou, Evaluation of carbon fiber dispersion in cement-based materials using mechanical properties, conductivity, mass variation coefficient, and microstructure, Construction and Building Materials 266 (2021) 120891.","https://doi.org/10.1016/j.conbuildmat.2020.120891","evalua~1.pdf" | |
| "PAPER_012","Effect of silane treatment on microstructure of sisal fibers.pdf","F. Zhou, G. Cheng, B. Jiang, Effect of silane treatment on microstructure of sisal fibers, Applied Surface Science (2014).","https://doi.org/10.1016/j.apsusc.2013.12.054","effect of silane treatment on microstructure of sisal fibers.pdf" | |
| "PAPER_013","Graphene family (GFMs), carbon nanotubes (CNTs) and carbon black (CB) on smart materials for civil construction.pdf","Graphene Family (Gfms), Carbon Nanotubes (Cnts) And Carbon Black (Cb) On Smart Materials For Civil Construction","https://doi.org/10.1016/j.jobe.2024.110175","graphene family (gfms), carbon nanotubes (cnts) and carbon black (cb) on smart materials for civil construction.pdf" | |
| "PAPER_014","Influence of the structures of polycarboxylate superplasticizer on its performance in cement-based materials-A review.pdf","S. Sha, M. Wang, C. Shi, Y. Xiao, Influence of the structures of polycarboxylate superplasticizer on its performance in cement-based materials-A review, Construction and Building Materials (2020).","https://doi.org/10.1016/j.conbuildmat.2019.117257","influence of the structures of polycarboxylate superplasticizer on its performance in cement-based materials-a review.pdf" | |
| "PAPER_015","Investigating the synergistic effects of carbon fiber and silica fume on concrete strength and eco-efficiency.pdf","A. Waqar, M. Khan, M. Afzal, D. Radu, T. Gălăţanu, et al., Investigating the synergistic effects of carbon fiber and silica fume on concrete strength and eco-efficiency, Case Studies in Construction Materials (2024).","https://doi.org/10.1016/j.cscm.2024.e02967","investigating the synergistic effects of carbon fiber and silica fume on concrete strength and eco-efficiency.pdf" | |
| "PAPER_016","Investigation of 3D Printed Self-Sensing UHPC Composites Using Graphite and Hybrid Carbon Microfibers.pdf","H. Liu, S. Laflamme, B. Cai, P. Lyu, S. Sritharan, et al., Investigation of 3D Printed Self-Sensing UHPC Composites Using Graphite and Hybrid Carbon Microfibers, Sensors (2024).","https://doi.org/10.3390/s24237638","investigation of 3d printed self-sensing uhpc composites using graphite and hybrid carbon microfibers.pdf" | |
| "PAPER_017","Ozone treatment of carbon fiber for reinforcing cement.pdf","X. Fu, W. Lu, D. Chung, Ozone treatment of carbon fiber for reinforcing cement, Carbon (1998).","https://doi.org/10.1016/s0008-6223(98)00115-8","ozone treatment of carbon fiber for reinforcing cement.pdf" | |
| "PAPER_018","PIEZOE~1.PDF","K. Shi, D. Chung, Piezoelectricity-based self-sensing of compressive and flexural stress in cement-based materials without admixture requirement and without poling, Smart Materials and Structures 27 (2018) 105011.","https://doi.org/10.1088/1361-665x/aad87f","piezoe~1.pdf" | |
| "PAPER_019","Performance of silica fume slurry treated recycled aggregate concrete reinforced with carbon fibers.pdf","M. Ashraf, M. Idrees, A. Akbar, Performance of silica fume slurry treated recycled aggregate concrete reinforced with carbon fibers, Journal of Building Engineering (2023).","https://doi.org/10.1016/j.jobe.2023.105892","performance of silica fume slurry treated recycled aggregate concrete reinforced with carbon fibers.pdf" | |
| "PAPER_020","Piezopermittivity for capacitance-based strain stress sensing.pdf","D. Chung, X. Xi, Piezopermittivity for capacitance-based strain/stress sensing, Sensors and Actuators A: Physical (2021).","https://doi.org/10.1016/j.sna.2021.113028","piezopermittivity for capacitance-based strain stress sensing.pdf" | |
| "PAPER_021","Review Improving cement-based materials by using silica fume.pdf","D. Chung, Review: Improving cement-based materials by using silica fume, Journal of Materials Science (2002).","https://doi.org/10.1023/a:1013889725971","review improving cement-based materials by using silica fume.pdf" | |
| "PAPER_022","Revolutionizing infrastructure The evolving landscape of electricity-based multifunctional concrete from concept to practice.pdf","H. Qin, S. Ding, A. Ashour, Q. Zheng, B. Han, Revolutionizing infrastructure: The evolving landscape of electricity-based multifunctional concrete from concept to practice, Progress in Materials Science (2024).","https://doi.org/10.1016/j.pmatsci.2024.101310","revolutionizing infrastructure the evolving landscape of electricity-based multifunctional concrete from concept to practice.pdf" | |
| "PAPER_023","S1-An-experimental-study-of-self-sensing-concrete-enhanced_2020_Construction-an.pdf","B. Han, L. Zhang, J. Ou, Self-Sensing Concrete, Smart and Multifunctional Concrete Toward Sustainable Infrastructures (2017).","https://doi.org/10.1007/978-981-10-4349-9_6","s1-an-experimental-study-of-self-sensing-concrete-enhanced_2020_construction-an.pdf" | |
| "PAPER_024","S10-Enhancing-self-stress-sensing-ability-of-smart-ultra-high_2021_Journal-of-Bu.pdf","H. Le, M. Kim, S. Kim, S. Chung, D. Kim, Enhancing self-stress sensing ability of smart ultra-high performance concretes under compression by using nano functional fillers, Journal of Building Engineering (2021).","https://doi.org/10.1016/j.jobe.2021.102717","s10-enhancing-self-stress-sensing-ability-of-smart-ultra-high_2021_journal-of-bu.pdf" | |
| "PAPER_025","S100-C~1.PDF","X. Wang, B. Cao, C. Vlachakis, A. Al-Tabbaa, S. Haigh, Characterization and piezo-resistivity studies on graphite-enabled self-sensing cementitious composites with high stress and strain sensitivity, Cement and Concrete Composites 142 (2023) 105187.","https://doi.org/10.1016/j.cemconcomp.2023.105187","s100-c~1.pdf" | |
| "PAPER_026","S11-Environment-Friendly, Self-Sensing Concrete Blended with Byproduct Wastes.pdf","S11 Environment Friendly, Self Sensing Concrete Blended With Byproduct Wastes","https://doi.org/10.3390/s20071925","s11-environment-friendly, self-sensing concrete blended with byproduct wastes.pdf" | |
| "PAPER_027","S12-Hybrid-effects-of-steel-fiber-and-carbon-nanotube-on-s_2018_Construction-and.pdf","E. Thostenson, W. Li, D. Wang, Z. Ren, T. Chou, Carbon nanotube/carbon fiber hybrid multiscale composites, Journal of Applied Physics (2002).","https://doi.org/10.1063/1.1466880","s12-hybrid-effects-of-steel-fiber-and-carbon-nanotube-on-s_2018_construction-and.pdf" | |
| "PAPER_028","S13-Increasing-self-sensing-capability-of-carbon-nanotubes-c_2020_Construction-a.pdf","T. Yin, J. Xu, Y. Wang, L. Liu, Increasing self-sensing capability of carbon nanotubes cement-based materials by simultaneous addition of Ni nanofibers with low content, Construction and Building Materials (2020).","https://doi.org/10.1016/j.conbuildmat.2020.119306","s13-increasing-self-sensing-capability-of-carbon-nanotubes-c_2020_construction-a.pdf" | |
| "PAPER_029","S14-Influence-of-carbon-nanofiber-content-and-sodium-chloride-_2019_Case-Studies.pdf","H. Wang, J. Shen, J. Liu, S. Lu, G. He, Influence of carbon nanofiber content and sodium chloride solution on the stability of resistance and the following self-sensing performance of carbon nanofiber cement paste, Case Studies in Construction Materials (2019).","https://doi.org/10.1016/j.cscm.2019.e00247","s14-influence-of-carbon-nanofiber-content-and-sodium-chloride-_2019_case-studies.pdf" | |
| "PAPER_030","S15-Influence-of-water-ingress-on-the-electrical-properties-_2021_Journal-of-Bui.pdf","D. Jang, H. Yoon, S. Farooq, H. Lee, I. Nam, Influence of water ingress on the electrical properties and electromechanical sensing capabilities of CNT/cement composites, Journal of Building Engineering (2021).","https://doi.org/10.1016/j.jobe.2021.103065","s15-influence-of-water-ingress-on-the-electrical-properties-_2021_journal-of-bui.pdf" | |
| "PAPER_031","S16-Investigations-on-scalable-fabrication-procedures-for-sel_2016_Cement-and-Co.pdf","A. D'Alessandro, M. Rallini, F. Ubertini, A. Materazzi, J. Kenny, Investigations on scalable fabrication procedures for self-sensing carbon nanotube cement-matrix composites for SHM applications, Cement and Concrete Composites (2016).","https://doi.org/10.1016/j.cemconcomp.2015.11.001","s16-investigations-on-scalable-fabrication-procedures-for-sel_2016_cement-and-co.pdf" | |
| "PAPER_032","S17-Cross tension and compression loading and large-scale testing of strain and damage sensing smart concrete.pdf","E. Demircilioğlu, E. Teomete, O. Ozbulut, S. Kahraman, Cross tension and compression loading and large-scale testing of strain and damage sensing smart concrete, Construction and Building Materials (2022).","https://doi.org/10.1016/j.conbuildmat.2021.125784","s17-cross tension and compression loading and large-scale testing of strain and damage sensing smart concrete.pdf" | |
| "PAPER_033","S18-Nano graphite platelets-enabled piezoresistive cementitious composites for structural health monitoring.pdf","S. Sun, B. Han, S. Jiang, X. Yu, Y. Wang, et al., Nano graphite platelets-enabled piezoresistive cementitious composites for structural health monitoring, Construction and Building Materials (2017).","https://doi.org/10.1016/j.conbuildmat.2017.01.006","s18-nano graphite platelets-enabled piezoresistive cementitious composites for structural health monitoring.pdf" | |
| "PAPER_034","S19-Self-sensing-piezoresistive-cement-composite-loaded_2017_Cement-and-Concrete.pdf","A. Monteiro, P. Cachim, P. Costa, Self-sensing piezoresistive cement composite loaded with carbon black particles, Cement and Concrete Composites (2017).","https://doi.org/10.1016/j.cemconcomp.2017.04.009","s19-self-sensing-piezoresistive-cement-composite-loaded_2017_cement-and-concrete.pdf" | |
| "PAPER_035","S2-Characterization-of-smart-brass-fiber-reinforced-co_2020_Construction-and-Bu.pdf","E. Demircilioğlu, E. Teomete, O. Ozbulut, Characterization of smart brass fiber reinforced concrete under various loading conditions, Construction and Building Materials (2020).","https://doi.org/10.1016/j.conbuildmat.2020.120411","s2-characterization-of-smart-brass-fiber-reinforced-co_2020_construction-and-bu.pdf" | |
| "PAPER_036","S20-IN~1.PDF","F. Baeza, O. Galao, I. Vegas, M. Cano, P. Garcés, Influence of recycled slag aggregates on the conductivity and strain sensing capacity of carbon fiber reinforced cement mortars, Construction and Building Materials 184 (2018) 311-319.","https://doi.org/10.1016/j.conbuildmat.2018.06.218","s20-in~1.pdf" | |
| "PAPER_037","S21-Mechanical, electrical and self-sensing properties of cementitious mortars containing short carbon fibers.pdf","S21 Mechanical, Electrical And Self Sensing Properties Of Cementitious Mortars Containing Short Carbon Fibers","https://doi.org/10.1016/j.jobe.2018.06.011","s21-mechanical, electrical and self-sensing properties of cementitious mortars containing short carbon fibers.pdf" | |
| "PAPER_038","S22-Improved strain sensing properties of cement-based sensors through enhanced carbon nanotube dispersion.pdf","A. D'Alessandro, M. Tiecco, A. Meoni, F. Ubertini, Improved strain sensing properties of cement-based sensors through enhanced carbon nanotube dispersion, Cement and Concrete Composites (2021).","https://doi.org/10.1016/j.cemconcomp.2020.103842","s22-improved strain sensing properties of cement-based sensors through enhanced carbon nanotube dispersion.pdf" | |
| "PAPER_039","S23-Increasing self-sensing capability of carbon nanotubes cement-based materials by simultaneous addition of Ni nanofibers.pdf","T. Yin, J. Xu, Y. Wang, L. Liu, Increasing self-sensing capability of carbon nanotubes cement-based materials by simultaneous addition of Ni nanofibers with low content, Construction and Building Materials (2020).","https://doi.org/10.1016/j.conbuildmat.2020.119306","s23-increasing self-sensing capability of carbon nanotubes cement-based materials by simultaneous addition of ni nanofibers.pdf" | |
| "PAPER_040","S24-Multifunctional-self-sensing-and-ductile-cementit_2019_Cement-and-Concrete-R.pdf","X. Li, M. Li, Multifunctional self-sensing and ductile cementitious materials, Cement and Concrete Research (2019).","https://doi.org/10.1016/j.cemconres.2019.03.008","s24-multifunctional-self-sensing-and-ductile-cementit_2019_cement-and-concrete-r.pdf" | |
| "PAPER_041","S25-Self-sensing-capability-of-ultra-high-performance-concr_2018_Sensors-and-Act.pdf","S25 Self Sensing Capability Of Ultra High Performance Concr 2018 Sensors And Act","https://doi.org/10.2139/ssrn.5342101","s25-self-sensing-capability-of-ultra-high-performance-concr_2018_sensors-and-act.pdf" | |
| "PAPER_042","S26-TE~1.PDF","B. del Moral, F. Baeza, R. Navarro, O. Galao, E. Zornoza, et al., Temperature and humidity influence on the strain sensing performance of hybrid carbon nanotubes and graphite cement composites, Construction and Building Materials 284 (2021) 122786.","https://doi.org/10.1016/j.conbuildmat.2021.122786","s26-te~1.pdf" | |
| "PAPER_043","S27-Effect of aspect ratio on strain sensing capacity of carbon fiber reinforced cement composites.pdf","F. Baeza, O. Galao, E. Zornoza, P. Garcés, Effect of aspect ratio on strain sensing capacity of carbon fiber reinforced cement composites, Materials & Design (2013).","https://doi.org/10.1016/j.matdes.2013.05.010","s27-effect of aspect ratio on strain sensing capacity of carbon fiber reinforced cement composites.pdf" | |
| "PAPER_044","S28-Smart Graphite–Cement Composites with Low Percolation Threshold.pdf","M. Frąc, P. Szołdra, W. Pichór, Smart Graphite–Cement Composites with Low Percolation Threshold, Materials (2022).","https://doi.org/10.3390/ma15082770","s28-smart graphite–cement composites with low percolation threshold.pdf" | |
| "PAPER_045","S29-Hybrid Carbon Microfibers-Graphite Fillers for Piezoresistive Cementitious Composites.pdf","H. Birgin, A. D’Alessandro, S. Laflamme, F. Ubertini, Hybrid Carbon Microfibers-Graphite Fillers for Piezoresistive Cementitious Composites, Sensors (2021).","https://doi.org/10.3390/s21020518","s29-hybrid carbon microfibers-graphite fillers for piezoresistive cementitious composites.pdf" | |
| "PAPER_046","S3-Effect of characteristics of assembly unit of CNTNCB composite fillers on properties of smart cement-based materials.pdf","L. Zhang, S. Ding, L. Li, S. Dong, D. Wang, et al., Effect of characteristics of assembly unit of CNT/NCB composite fillers on properties of smart cement-based materials, Composites Part A: Applied Science and Manufacturing (2018).","https://doi.org/10.1016/j.compositesa.2018.03.020","s3-effect of characteristics of assembly unit of cntncb composite fillers on properties of smart cement-based materials.pdf" | |
| "PAPER_047","S30-Smart Graphite–Cement Composite for Roadway-Integrated Weigh-In-Motion Sensing.pdf","H. Birgin, A. D’Alessandro, S. Laflamme, F. Ubertini, Smart Graphite–Cement Composite for Roadway-Integrated Weigh-In-Motion Sensing, Sensors (2020).","https://doi.org/10.3390/s20164518","s30-smart graphite–cement composite for roadway-integrated weigh-in-motion sensing.pdf" | |
| "PAPER_048","S31-Electrical and piezoresistive properties of carbon nanofiber cement mortar under different temperatures and water contents.pdf","H. Wang, A. Zhang, L. Zhang, Q. Wang, X. Yang, et al., Electrical and piezoresistive properties of carbon nanofiber cement mortar under different temperatures and water contents, Construction and Building Materials (2020).","https://doi.org/10.1016/j.conbuildmat.2020.120740","s31-electrical and piezoresistive properties of carbon nanofiber cement mortar under different temperatures and water contents.pdf" | |
| "PAPER_049","S32-Self-stress-sensing-smart-concrete-containing-fine-stee_2019_Construction-an.pdf","S. Lee, H. Le, D. Kim, Self-stress sensing smart concrete containing fine steel slag aggregates and steel fibers under high compressive stress, Construction and Building Materials (2019).","https://doi.org/10.1016/j.conbuildmat.2019.05.197","s32-self-stress-sensing-smart-concrete-containing-fine-stee_2019_construction-an.pdf" | |
| "PAPER_050","S33-IN~1.PDF","W. Dong, W. Li, Z. Sun, I. Ibrahim, D. Sheng, Intrinsic graphene/cement-based sensors with piezoresistivity and superhydrophobicity capacities for smart concrete infrastructure, Automation in Construction 133 (2022) 103983.","https://doi.org/10.1016/j.autcon.2021.103983","s33-in~1.pdf" | |
| "PAPER_051","S34-Self-sensing-ultra-high-performance-concrete-fo_2021_Sensors-and-Actuators-A.pdf","S34 Self Sensing Ultra High Performance Concrete Fo 2021 Sensors And Actuators A","https://doi.org/10.2139/ssrn.5342101","s34-self-sensing-ultra-high-performance-concrete-fo_2021_sensors-and-actuators-a.pdf" | |
| "PAPER_052","S35-EL~1.PDF","Y. Hou, M. Sun, J. Chen, Electrical resistance and capacitance responses of smart ultra-high performance concrete with compressive strain by DC and AC measurements, Construction and Building Materials 327 (2022) 127007.","https://doi.org/10.1016/j.conbuildmat.2022.127007","s35-el~1.pdf" | |
| "PAPER_053","S36-Piezoresistivity enhancement of functional carbon black filled cement-based sensor using polypropylene fibre.pdf","W. Dong, W. Li, K. Wang, Y. Guo, D. Sheng, et al., Piezoresistivity enhancement of functional carbon black filled cement-based sensor using polypropylene fibre, Powder Technology (2020).","https://doi.org/10.1016/j.powtec.2020.06.029","s36-piezoresistivity enhancement of functional carbon black filled cement-based sensor using polypropylene fibre.pdf" | |
| "PAPER_054","S37-Test and Study on Electrical Property of Conductive Concrete.pdf","X. Tian, H. Hu, Test and Study on Electrical Property of Conductive Concrete, Procedia Earth and Planetary Science (2012).","https://doi.org/10.1016/j.proeps.2012.01.014","s37-test and study on electrical property of conductive concrete.pdf" | |
| "PAPER_055","S38 - Electrical-resistance-based Sensing of Impact Damage in Carbon Fiber Reinforced Cement-based Materials.pdf","D. Meehan, . Shoukai Wang, D. Chung, Electrical-resistance-based Sensing of Impact Damage in Carbon Fiber Reinforced Cement-based Materials, Journal of Intelligent Material Systems and Structures (2010).","https://doi.org/10.1177/1045389x09354786","s38 - electrical-resistance-based sensing of impact damage in carbon fiber reinforced cement-based materials.pdf" | |
| "PAPER_056","S39 - Electrical conductivity of self-monitoring CFRC.pdf","M. Chiarello, R. Zinno, Electrical conductivity of self-monitoring CFRC, Cement and Concrete Composites (2005).","https://doi.org/10.1016/j.cemconcomp.2004.09.001","s39 - electrical conductivity of self-monitoring cfrc.pdf" | |
| "PAPER_057","S4-Effect-of-steel-fiber-and-carbon-black-on-the-self-s_2019_Construction-and-B.pdf","Y. Ding, G. Liu, A. Hussain, F. Pacheco-Torgal, Y. Zhang, Effect of steel fiber and carbon black on the self-sensing ability of concrete cracks under bending, Construction and Building Materials (2019).","https://doi.org/10.1016/j.conbuildmat.2019.02.160","s4-effect-of-steel-fiber-and-carbon-black-on-the-self-s_2019_construction-and-b.pdf" | |
| "PAPER_058","S40 - Resistance Changes during Compression of Carbon Fiber Cement COmposites.pdf","F. Reza, G. Batson, J. Yamamuro, J. Lee, Resistance Changes during Compression of Carbon Fiber Cement Composites, Journal of Materials in Civil Engineering (2003).","https://doi.org/10.1061/(asce)0899-1561(2003)15:5(476)","s40 - resistance changes during compression of carbon fiber cement composites.pdf" | |
| "PAPER_059","S41 - Electrical-resistance-based damage self-sensing in carbon fiber reinforced cement.pdf","S. Wen, D. Chung, Electrical-resistance-based damage self-sensing in carbon fiber reinforced cement, Carbon (2007).","https://doi.org/10.1016/j.carbon.2006.11.029","s41 - electrical-resistance-based damage self-sensing in carbon fiber reinforced cement.pdf" | |
| "PAPER_060","S42-SE~1.PDF","M. Konsta-Gdoutos, C. Aza, Self sensing carbon nanotube (CNT) and nanofiber (CNF) cementitious composites for real time damage assessment in smart structures, Cement and Concrete Composites 53 (2014) 162-169.","https://doi.org/10.1016/j.cemconcomp.2014.07.003","s42-se~1.pdf" | |
| "PAPER_061","S43 - the 100th anniversary of the four-point probe technique the role of probe geometries in isotropic andanisotropic systems.pdf","I. Miccoli, F. Edler, H. Pfnür, C. Tegenkamp, The 100th anniversary of the four-point probe technique: the role of probe geometries in isotropic and anisotropic systems, Journal of Physics: Condensed Matter (2015).","https://doi.org/10.1088/0953-8984/27/22/223201","s43 - the 100th anniversary of the four-point probe technique the role of probe geometries in isotropic andanisotropic systems.pdf" | |
| "PAPER_062","S44-Sensing performance of engineered cementitious composites in different application forms.pdf","J. Han, J. Pan, X. Ma, J. Cai, Sensing performance of engineered cementitious composites in different application forms, Construction and Building Materials (2022).","https://doi.org/10.1016/j.conbuildmat.2022.129223","s44-sensing performance of engineered cementitious composites in different application forms.pdf" | |
| "PAPER_063","S45-Insitu synthesizing carbon nanotubes on cement to develop self-sensing cementitious composites.pdf","S. Ding, Y. Xiang, Y. Ni, V. Thakur, X. Wang, et al., In-situ synthesizing carbon nanotubes on cement to develop self-sensing cementitious composites for smart high-speed rail infrastructures, Nano Today (2022).","https://doi.org/10.1016/j.nantod.2022.101438","s45-insitu synthesizing carbon nanotubes on cement to develop self-sensing cementitious composites.pdf" | |
| "PAPER_064","S46-SE~1.PDF","D. Wang, S. Dong, X. Wang, N. Maimaitituersun, S. Shao, et al., Sensing performances of hybrid steel wires and fibers reinforced ultra-high performance concrete for in-situ monitoring of infrastructures, Journal of Building Engineering 58 (2022) 105022.","https://doi.org/10.1016/j.jobe.2022.105022","s46-se~1.pdf" | |
| "PAPER_065","S47-The applicability of shungite as an electrically conductive additive in cement composites.pdf","M. Frąc, W. Szudek, P. Szołdra, W. Pichór, The applicability of shungite as an electrically conductive additive in cement composites, Journal of Building Engineering (2022).","https://doi.org/10.1016/j.jobe.2021.103469","s47-the applicability of shungite as an electrically conductive additive in cement composites.pdf" | |
| "PAPER_066","S48-Self-sensing properties and piezoresistive effect of high ductility cementitious composite.pdf","J. Han, J. Pan, J. Cai, Self-sensing properties and piezoresistive effect of high ductility cementitious composite, Construction and Building Materials (2022).","https://doi.org/10.1016/j.conbuildmat.2022.126390","s48-self-sensing properties and piezoresistive effect of high ductility cementitious composite.pdf" | |
| "PAPER_067","S49-ME~1.PDF","W. Dong, W. Li, Y. Guo, K. Wang, D. Sheng, Mechanical properties and piezoresistive performances of intrinsic graphene nanoplate/cement-based sensors subjected to impact load, Construction and Building Materials 327 (2022) 126978.","https://doi.org/10.1016/j.conbuildmat.2022.126978","s49-me~1.pdf" | |
| "PAPER_068","S5-Effects-of-carbon-nanomaterial-type-and-amount-on-self-sensing-_2019_Measure.pdf","D. Yoo, I. You, G. Zi, S. Lee, Effects of carbon nanomaterial type and amount on self-sensing capacity of cement paste, Measurement (2019).","https://doi.org/10.1016/j.measurement.2018.11.024","s5-effects-of-carbon-nanomaterial-type-and-amount-on-self-sensing-_2019_measure.pdf" | |
| "PAPER_069","S50-IM~1.PDF","L. Liu, J. Xu, T. Yin, Y. Wang, H. Chu, Improving electrical and piezoresistive properties of cement-based composites by combined addition of nano carbon black and nickel nanofiber, Journal of Building Engineering 51 (2022) 104312.","https://doi.org/10.1016/j.jobe.2022.104312","s50-im~1.pdf" | |
| "PAPER_070","S51-Electrical and piezoresistive properties of cement composites with carbon nanomaterials.pdf","D. Yoo, I. You, H. Youn, S. Lee, Electrical and piezoresistive properties of cement composites with carbon nanomaterials, Journal of Composite Materials (2018).","https://doi.org/10.1177/0021998318764809","s51-electrical and piezoresistive properties of cement composites with carbon nanomaterials.pdf" | |
| "PAPER_071","S52-Influences of (MCNT) fraction, moisture, stressstrain level on the electrical properties of MCNT of cement-based composites.pdf","S52 Influences Of (Mcnt) Fraction, Moisture, Stressstrain Level On The Electrical Properties Of Mcnt Of Cement Based Composites","https://doi.org/10.1016/j.sna.2018.08.010","s52-influences of (mcnt) fraction, moisture, stressstrain level on the electrical properties of mcnt of cement-based composites.pdf" | |
| "PAPER_072","S53-CA~1.PDF","A. D’Alessandro, H. Birgin, F. Ubertini, Carbon Microfiber-Doped Smart Concrete Sensors for Strain Monitoring in Reinforced Concrete Structures: An Experimental Study at Various Scales, Sensors 22 (2022) 6083.","https://doi.org/10.3390/s22166083","s53-ca~1.pdf" | |
| "PAPER_073","S54-Carbon Nanofibers Grown in CaO for Self-Sensing in Mortar.pdf","L. de Souza, M. Pimentel, G. Milone, J. Tristão, A. Al-Tabbaa, Carbon Nanofibers Grown in CaO for Self-Sensing in Mortar, Materials (2022).","https://doi.org/10.3390/ma15144951","s54-carbon nanofibers grown in cao for self-sensing in mortar.pdf" | |
| "PAPER_074","S55-Electro-mechanical self-sensing response of ultra-high-performance fiber-reinforced concrete in tension.pdf","M. Kim, D. Kim, Y. An, Electro-mechanical self-sensing response of ultra-high-performance fiber-reinforced concrete in tension, Composites Part B: Engineering (2018).","https://doi.org/10.1016/j.compositesb.2017.09.061","s55-electro-mechanical self-sensing response of ultra-high-performance fiber-reinforced concrete in tension.pdf" | |
| "PAPER_075","S55-Nanocarbon black-based ultra-high-performance concrete (UHPC) with self-strain sensing capability.pdf","A. Hussain, Y. Xiang, T. Yu, F. Zou, Nanocarbon black-based ultra-high-performance concrete (UHPC) with self-strain sensing capability, Construction and Building Materials (2022).","https://doi.org/10.1016/j.conbuildmat.2022.129496","s55-nanocarbon black-based ultra-high-performance concrete (uhpc) with self-strain sensing capability.pdf" | |
| "PAPER_076","S56-Self-sensing cementitious composites incorporated with botryoid hybrid nano-carbon materials for smart infrastructures.pdf","B. Han, Y. Wang, S. Ding, X. Yu, L. Zhang, et al., Self-sensing cementitious composites incorporated with botryoid hybrid nano-carbon materials for smart infrastructures, Journal of Intelligent Material Systems and Structures (2017).","https://doi.org/10.1177/1045389x16657416","s56-self-sensing cementitious composites incorporated with botryoid hybrid nano-carbon materials for smart infrastructures.pdf" | |
| "PAPER_077","S57-IN~1.PDF","W. Dong, W. Li, K. Wang, B. Han, D. Sheng, et al., Investigation on physicochemical and piezoresistive properties of smart MWCNT/cementitious composite exposed to elevated temperatures, Cement and Concrete Composites 112 (2020) 103675.","https://doi.org/10.1016/j.cemconcomp.2020.103675","s57-in~1.pdf" | |
| "PAPER_078","S58-DE~1.PDF","Y. Wang, L. Zhang, Development of self-sensing cementitious composite incorporating hybrid graphene nanoplates and carbon nanotubes for structural health monitoring, Sensors and Actuators A: Physical 336 (2022) 113367.","https://doi.org/10.1016/j.sna.2022.113367","s58-de~1.pdf" | |
| "PAPER_079","S59-Modifying self-sensing cement-based composites through multiscale composition.pdf","S. Dong, W. Zhang, D. Wang, X. Wang, B. Han, Modifying self-sensing cement-based composites through multiscale composition, Measurement Science and Technology (2021).","https://doi.org/10.1088/1361-6501/abdfed","s59-modifying self-sensing cement-based composites through multiscale composition.pdf" | |
| "PAPER_080","S6-Electrically conductive behaviors and mechanisms of short-cut super-fine stainless wire reinforced reactive powder concrete.pdf","S. Dong, B. Han, J. Ou, Z. Li, L. Han, et al., Electrically conductive behaviors and mechanisms of short-cut super-fine stainless wire reinforced reactive powder concrete, Cement and Concrete Composites (2016).","https://doi.org/10.1016/j.cemconcomp.2016.05.022","s6-electrically conductive behaviors and mechanisms of short-cut super-fine stainless wire reinforced reactive powder concrete.pdf" | |
| "PAPER_081","S60-Study on self-sensing capabilities of smart cements filled with graphene oxide under dynamic cyclic loading.pdf","Y. Suo, H. Xia, R. Guo, Y. Yang, Study on self-sensing capabilities of smart cements filled with graphene oxide under dynamic cyclic loading, Journal of Building Engineering (2022).","https://doi.org/10.1016/j.jobe.2022.104775","s60-study on self-sensing capabilities of smart cements filled with graphene oxide under dynamic cyclic loading.pdf" | |
| "PAPER_082","S61-Piezoresistivity, mechanisms and model of cement-based materials with CNT_NCB composite fillers.pdf","S61 Piezoresistivity, Mechanisms And Model Of Cement Based Materials With Cnt Ncb Composite Fillers","https://doi.org/10.1088/2053-1591/aa9d1d","s61-piezoresistivity, mechanisms and model of cement-based materials with cnt_ncb composite fillers.pdf" | |
| "PAPER_083","S62-MU~1.PDF","A. Pisello, A. D’Alessandro, S. Sambuco, M. Rallini, F. Ubertini, et al., Multipurpose experimental characterization of smart nanocomposite cement-based materials for thermal-energy efficiency and strain-sensing capability, Solar Energy Materials and Solar Cells 161 (2017) 77-88.","https://doi.org/10.1016/j.solmat.2016.11.030","s62-mu~1.pdf" | |
| "PAPER_084","S63-Piezoresistive properties of cement composites with expanded graphite.pdf","M. Frąc, W. Pichór, Piezoresistive properties of cement composites with expanded graphite, Composites Communications (2020).","https://doi.org/10.1016/j.coco.2020.03.005","s63-piezoresistive properties of cement composites with expanded graphite.pdf" | |
| "PAPER_085","S64-Electrical Properties of Cement-Based Composites with Carbon Nanotubes, Graphene, and Graphite Nanofibers.pdf","S64 Electrical Properties Of Cement Based Composites With Carbon Nanotubes, Graphene, And Graphite Nanofibers","https://doi.org/10.3390/s17051064","s64-electrical properties of cement-based composites with carbon nanotubes, graphene, and graphite nanofibers.pdf" | |
| "PAPER_086","S65-AN~1.PDF","A. Meoni, A. D'Alessandro, A. Downey, E. García-Macías, M. Rallini, et al., An Experimental Study on Static and Dynamic Strain Sensitivity of Smart Concrete Sensors Doped with Carbon Nanotubes for SHM of Large Structures, Unknown Journal () .","https://doi.org/10.20944/preprints201802.0063.v1","s65-an~1.pdf" | |
| "PAPER_087","S66-Experimental Investigation of the Piezoresistive Properties of Cement Composites with Hybrid Carbon Fibers and Nanotubes.pdf","S. Lee, I. You, G. Zi, D. Yoo, Experimental Investigation of the Piezoresistive Properties of Cement Composites with Hybrid Carbon Fibers and Nanotubes, Sensors (2017).","https://doi.org/10.3390/s17112516","s66-experimental investigation of the piezoresistive properties of cement composites with hybrid carbon fibers and nanotubes.pdf" | |
| "PAPER_088","S67-Strain and damage sensing properties on multifunctional cement composites with CNF admixture.pdf","O. Galao, F. Baeza, E. Zornoza, P. Garcés, Strain and damage sensing properties on multifunctional cement composites with CNF admixture, Cement and Concrete Composites (2014).","https://doi.org/10.1016/j.cemconcomp.2013.11.009","s67-strain and damage sensing properties on multifunctional cement composites with cnf admixture.pdf" | |
| "PAPER_089","S68-EF~1.PDF","G. Nalon, J. Ribeiro, E. Araújo, L. Pedroti, J. Carvalho, et al., Effects of different kinds of carbon black nanoparticles on the piezoresistive and mechanical properties of cement-based composites, Journal of Building Engineering 32 (2020) 101724.","https://doi.org/10.1016/j.jobe.2020.101724","s68-ef~1.pdf" | |
| "PAPER_090","S69-Cement-based sensors with carbon fibers and carbon nanotubes for piezoresistive sensing.pdf","F. Azhari, N. Banthia, Cement-based sensors with carbon fibers and carbon nanotubes for piezoresistive sensing, Cement and Concrete Composites (2012).","https://doi.org/10.1016/j.cemconcomp.2012.04.007","s69-cement-based sensors with carbon fibers and carbon nanotubes for piezoresistive sensing.pdf" | |
| "PAPER_091","S7-Electrical characteristics and pressure-sensitive response measurements of carboxyl MWNT_cement composites.pdf","B. Han, K. Zhang, X. Yu, E. Kwon, J. Ou, Electrical characteristics and pressure-sensitive response measurements of carboxyl MWNT/cement composites, Cement and Concrete Composites (2012).","https://doi.org/10.1016/j.cemconcomp.2012.02.012","s7-electrical characteristics and pressure-sensitive response measurements of carboxyl mwnt_cement composites.pdf" | |
| "PAPER_092","S70-EV~1.PDF","A. Belli, A. Mobili, T. Bellezze, F. Tittarelli, P. Cachim, Evaluating the Self-Sensing Ability of Cement Mortars Manufactured with Graphene Nanoplatelets, Virgin or Recycled Carbon Fibers through Piezoresistivity Tests, Sustainability 10 (2018) 4013.","https://doi.org/10.3390/su10114013","s70-ev~1.pdf" | |
| "PAPER_093","S71-Enhanced sensing performance of cement-based composites achieved via magnetically aligned nickel particle network.pdf","Z. Tian, S. Li, Y. Li, Enhanced sensing performance of cement-based composites achieved via magnetically aligned nickel particle network, Composites Communications (2022).","https://doi.org/10.1016/j.coco.2021.101006","s71-enhanced sensing performance of cement-based composites achieved via magnetically aligned nickel particle network.pdf" | |
| "PAPER_094","S72-Anisotropic electrical and piezoresistive sensing properties of cement-based sensors with aligned carbon fibers.pdf","J. Xu, T. Yin, Y. Wang, L. Liu, Anisotropic electrical and piezoresistive sensing properties of cement-based sensors with aligned carbon fibers, Cement and Concrete Composites (2021).","https://doi.org/10.1016/j.cemconcomp.2020.103873","s72-anisotropic electrical and piezoresistive sensing properties of cement-based sensors with aligned carbon fibers.pdf" | |
| "PAPER_095","S73-Development of self-sensing cement-based sensor using recycled fine waste glass aggregates coated with carbon nanotube.pdf","W. Dong, Y. Guo, Z. Sun, Z. Tao, W. Li, Development of piezoresistive cement-based sensor using recycled waste glass cullets coated with carbon nanotubes, Journal of Cleaner Production (2021).","https://doi.org/10.1016/j.jclepro.2021.127968","s73-development of self-sensing cement-based sensor using recycled fine waste glass aggregates coated with carbon nanotube.pdf" | |
| "PAPER_096","S74-Strain sensitivity of steel-fiber-reinforced industrial smart concrete.pdf","E. Demircilioglu, E. Teomete, O. Ozbulut, Strain sensitivity of steel-fiber-reinforced industrial smart concrete, Journal of Intelligent Material Systems and Structures (2020).","https://doi.org/10.1177/1045389x19888722","s74-strain sensitivity of steel-fiber-reinforced industrial smart concrete.pdf" | |
| "PAPER_097","S75-SE~1.PDF","M. Konsta-Gdoutos, C. Aza, Self sensing carbon nanotube (CNT) and nanofiber (CNF) cementitious composites for real time damage assessment in smart structures, Cement and Concrete Composites 53 (2014) 162-169.","https://doi.org/10.1016/j.cemconcomp.2014.07.003","s75-se~1.pdf" | |
| "PAPER_098","S76-Strain-sensing characteristics of self-consolidating concrete with micro-carbon fibre.pdf","A. Cholker, M. Tantray, Strain-sensing characteristics of self-consolidating concrete with micro-carbon fibre, Australian Journal of Civil Engineering (2020).","https://doi.org/10.1080/14488353.2019.1704206","s76-strain-sensing characteristics of self-consolidating concrete with micro-carbon fibre.pdf" | |
| "PAPER_099","S77-SE~1.PDF","Y. Guo, W. Li, W. Dong, Z. Luo, F. Qu, et al., Self-sensing performance of cement-based sensor with carbon black and polypropylene fibre subjected to different loading conditions, Journal of Building Engineering 59 (2022) 105003.","https://doi.org/10.1016/j.jobe.2022.105003","s77-se~1.pdf" | |
| "PAPER_100","S78-Mechanical and self-sensing properties of concrete reinforced with carbon nanofibres.pdf","F. Faghih, A. Ayoub, Mechanical and self-sensing properties of concrete reinforced with carbon nanofibres, Advances in Cement Research (2021).","https://doi.org/10.1680/jadcr.18.00209","s78-mechanical and self-sensing properties of concrete reinforced with carbon nanofibres.pdf" | |
| "PAPER_101","S79-Carbon nanotube cement-based transducers for dynamic sensing of strain.pdf","A. Materazzi, F. Ubertini, A. D’Alessandro, Carbon nanotube cement-based transducers for dynamic sensing of strain, Cement and Concrete Composites (2013).","https://doi.org/10.1016/j.cemconcomp.2012.12.013","s79-carbon nanotube cement-based transducers for dynamic sensing of strain.pdf" | |
| "PAPER_102","S8-Electrically-cured-ultra-high-performance-concrete--UHPC--embe_2020_Material.pdf","M. Jung, J. Park, S. Hong, J. Moon, Electrically cured ultra-high performance concrete (UHPC) embedded with carbon nanotubes for field casting and crack sensing, Materials & Design (2020).","https://doi.org/10.1016/j.matdes.2020.109127","s8-electrically-cured-ultra-high-performance-concrete--uhpc--embe_2020_material.pdf" | |
| "PAPER_103","S80-MA~1.PDF","J. Seo, D. Jang, B. Yang, H. Yoon, J. Jang, et al., Material characterization and piezoresistive sensing capability assessment of thin-walled CNT-embedded ultra-high performance concrete, Cement and Concrete Composites 134 (2022) 104808.","https://doi.org/10.1016/j.cemconcomp.2022.104808","s80-ma~1.pdf" | |
| "PAPER_104","S81-Piezoresistive properties of ultra-high-performance fiber-reinforced concrete incorporating few-layer graphene.pdf","F. Song, Q. Chen, Z. Jiang, X. Zhu, B. Li, et al., Piezoresistive properties of ultra-high-performance fiber-reinforced concrete incorporating few-layer graphene, Construction and Building Materials (2021).","https://doi.org/10.1016/j.conbuildmat.2021.124362","s81-piezoresistive properties of ultra-high-performance fiber-reinforced concrete incorporating few-layer graphene.pdf" | |
| "PAPER_105","S82-SY~1.PDF","R. Rao, B. Sindu, S. Sasmal, Synthesis, design and piezo-resistive characteristics of cementitious smart nanocomposites with different types of functionalized MWCNTs under long cyclic loading, Cement and Concrete Composites 108 (2020) 103517.","https://doi.org/10.1016/j.cemconcomp.2020.103517","s82-sy~1.pdf" | |
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| "PAPER_107","S84-TA~1.PDF",". , R. ZHANG, Z. HUANG, . , D. SUN, et al., Crystallization of Poly(L-lactide) in a Confined Space between Polycarbonate Layers, JOURNAL OF POLYMER MATERIALS (2018).","https://doi.org/10.32381/jpm.2018.35.02.3","s84-ta~1.pdf" | |
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| "PAPER_109","S86-EL~1.PDF",". , X. Wang, Z. Li, . , B. Han, et al., Intelligent Concrete with Self-x Capabilities for Smart Cities, Journal of Smart Cities (2017).","https://doi.org/10.26789/jsc.2016.02.005","s86-el~1.pdf" | |
| "PAPER_110","S87-EL~1.PDF","S. Sasmal, N. Ravivarman, B. Sindu, K. Vignesh, Electrical conductivity and piezo-resistive characteristics of CNT and CNF incorporated cementitious nanocomposites under static and dynamic loading, Composites Part A: Applied Science and Manufacturing 100 (2017) 227-243.","https://doi.org/10.1016/j.compositesa.2017.05.018","s87-el~1.pdf" | |
| "PAPER_111","S88-ST~1.PDF","L. Wang, F. Aslani, Structural performance of reinforced concrete beams with 3D printed cement-based sensor embedded and self-sensing cementitious composites, Engineering Structures 275 (2023) 115266.","https://doi.org/10.1016/j.engstruct.2022.115266","s88-st~1.pdf" | |
| "PAPER_112","S89-Piezoresistivity of carbon fiber graphite cement-based composites with CCCW.pdf","X. Fan, D. Fang, M. Sun, Z. Li, Piezoresistivity of carbon fiber graphite cement-based composites with CCCW, Journal of Wuhan University of Technology-Mater. Sci. Ed. (2011).","https://doi.org/10.1007/s11595-011-0226-0","s89-piezoresistivity of carbon fiber graphite cement-based composites with cccw.pdf" | |
| "PAPER_113","S9-Electro-mechanical-self-sensing-response-of-ultra-high-_2018_Composites-Part.pdf","M. Kim, D. Kim, Y. An, Electro-mechanical self-sensing response of ultra-high-performance fiber-reinforced concrete in tension, Composites Part B: Engineering (2018).","https://doi.org/10.1016/j.compositesb.2017.09.061","s9-electro-mechanical-self-sensing-response-of-ultra-high-_2018_composites-part.pdf" | |
| "PAPER_114","S90-EX~1.PDF","B. Han, B. Han, J. Ou, Experimental study on use of nickel powder-filled Portland cement-based composite for fabrication of piezoresistive sensors with high sensitivity, Sensors and Actuators A: Physical 149 (2009) 51-55.","https://doi.org/10.1016/j.sna.2008.10.001","s90-ex~1.pdf" | |
| "PAPER_115","S91-A comparative study on the influences of CNT and GNP on the piezoresistivity of cement composites.pdf","J. Tao, J. Wang, Q. Zeng, A comparative study on the influences of CNT and GNP on the piezoresistivity of cement composites, Materials Letters (2020).","https://doi.org/10.1016/j.matlet.2019.126858","s91-a comparative study on the influences of cnt and gnp on the piezoresistivity of cement composites.pdf" | |
| "PAPER_116","S92-Research-on-the-self-sensing-and-mechanical-properties-of_2021_Cement-and-Co.pdf","S. Marçula, J. Silva, C. Silva, R. Lintz, L. Gachet, Analysis of Electrical and Mechanical Properties of Self-Sensing Cement Composite with Carbon Microfiber, Materials Research (2025).","https://doi.org/10.1590/1980-5373-mr-2025-0031","s92-research-on-the-self-sensing-and-mechanical-properties-of_2021_cement-and-co.pdf" | |
| "PAPER_117","S93-Enhanced effects of carbon-based conductive materials on the piezoresistive characteristics of cementitious composites.pdf","J. Kim, Enhanced effects of carbon-based conductive materials on the piezoresistive characteristics of cementitious composites, Construction and Building Materials (2022).","https://doi.org/10.1016/j.conbuildmat.2022.127804","s93-enhanced effects of carbon-based conductive materials on the piezoresistive characteristics of cementitious composites.pdf" | |
| "PAPER_118","S94-The Utilization of Pearson’s Method to Analyze Piezoresistive Effect in Self-Sensing Cement Composite with Graphite.pdf","J. Silva, R. Lintz, L. Gachet, The Utilization of Pearson’s Method to Analyze Piezoresistive Effect in Self-Sensing Cement Composite with Graphite, Materials Research (2022).","https://doi.org/10.1590/1980-5373-mr-2022-0051","s94-the utilization of pearson’s method to analyze piezoresistive effect in self-sensing cement composite with graphite.pdf" | |
| "PAPER_119","S95-SE~1.PDF","A. Dinesh, D. Suji, M. Pichumani, Self-sensing cementitious composite sensor with integrated steel fiber and carbonaceous powder for real-time application in large-scale infrastructures, Sensors and Actuators A: Physical 353 (2023) 114209.","https://doi.org/10.1016/j.sna.2023.114209","s95-se~1.pdf" | |
| "PAPER_120","S96-EL~1.PDF","Y. Hou, M. Sun, J. Chen, Electrical resistance and capacitance responses of smart ultra-high performance concrete with compressive strain by DC and AC measurements, Construction and Building Materials 327 (2022) 127007.","https://doi.org/10.1016/j.conbuildmat.2022.127007","s96-el~1.pdf" | |
| "PAPER_121","S97-Self-sensing GFRP-reinforced concrete beams containing carbon nanotube-nano carbon black composite fillers.pdf","L. Qiu, S. Ding, D. Wang, B. Han, Self-sensing GFRP-reinforced concrete beams containing carbon nanotube-nano carbon black composite fillers, Measurement Science and Technology (2023).","https://doi.org/10.1088/1361-6501/accc20","s97-self-sensing gfrp-reinforced concrete beams containing carbon nanotube-nano carbon black composite fillers.pdf" | |
| "PAPER_122","S98-MI~1.PDF","G. Lima, G. Nalon, R. Santos, J. Ribeiro, J. Carvalho, et al., Microstructural Investigation of the Effects of Carbon Black Nanoparticles on Hydration Mechanisms, Mechanical and Piezoresistive Properties of Cement Mortars, Materials Research 24 (2021) .","https://doi.org/10.1590/1980-5373-mr-2020-0539","s98-mi~1.pdf" | |
| "PAPER_123","S99-Commercial and recycled carbon-based fillers and fibers for self-sensing cement-based composites.pdf","A. Belli, A. Mobili, T. Bellezze, P. Cachim, F. Tittarelli, Commercial and recycled carbon-based fillers and fibers for self-sensing cement-based composites: Comparison of mechanical strength, durability, and piezoresistive behavior, Journal of Building Engineering (2023).","https://doi.org/10.1016/j.jobe.2023.106836","s99-commercial and recycled carbon-based fillers and fibers for self-sensing cement-based composites.pdf" | |
| "PAPER_124","Self-sensing enhancement in smart ultra-high performance concrete composites via multi-scale carbon black.pdf","W. Xu, K. Shu, D. Fan, R. Yu, Self-sensing enhancement in smart ultra-high performance concrete composites via multi-scale carbon black: Insights from micro to macro characteristics, Composites Part B: Engineering (2025).","https://doi.org/10.1016/j.compositesb.2025.112645","self-sensing enhancement in smart ultra-high performance concrete composites via multi-scale carbon black.pdf" | |
| "PAPER_125","Self-sensing performance of cementitious composites with functional fillers at macro, micro and nano scales.pdf","Self Sensing Performance Of Cementitious Composites With Functional Fillers At Macro, Micro And Nano Scales","https://doi.org/10.1016/j.conbuildmat.2021.125679","self-sensing performance of cementitious composites with functional fillers at macro, micro and nano scales.pdf" | |
| "PAPER_126","Self‐Sensing Cementitious Composites with Hierarchical Carbon Fiber‐Carbon Nanotube Composite Fillers.pdf","S. Ding, X. Wang, L. Qiu, Y. Ni, X. Dong, et al., Self‐Sensing Cementitious Composites with Hierarchical Carbon Fiber‐Carbon Nanotube Composite Fillers for Crack Development Monitoring of a Maglev Girder, Small (2023).","https://doi.org/10.1002/smll.202206258","self‐sensing cementitious composites with hierarchical carbon fiber‐carbon nanotube composite fillers.pdf" | |
| "PAPER_127","Silane treatment of bagasse fiber for reinforcement of cementitious composites.pdf","K. Bilba, M. Arsene, Silane treatment of bagasse fiber for reinforcement of cementitious composites, Composites Part A: Applied Science and Manufacturing (2008).","https://doi.org/10.1016/j.compositesa.2008.05.013","silane treatment of bagasse fiber for reinforcement of cementitious composites.pdf" | |
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