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Cement and lime currently are the most common binders in building materials. However, alternative materials and methods are needed to overcome the functional limitations and environmental footprint of conventional products. This Special Issue dedicated to “New frontiers in cementitious and lime-based materials and composites” gathers selected reviews and experimental articles that showcase the most recent trends in this multidisciplinary field. Authoritative contributions from all around the world provide important insights into all areas of research related to cementitious and lime-based materials and composites, spanning from structural engineering to geotechnics, including materials science and processing technology. This Topical Collection is intended to foster innovation and help researchers and developers to identify new solutions for a more sustainable and functional built environment.

durability --- hardened properties --- green composite --- fresh properties --- recycled concrete aggregates --- natural coarse aggregates --- enzyme-induced calcite precipitation --- microbial-induced calcite precipitation --- geotechnical engineering --- geoenvironmental engineering --- precast concrete wall --- interfacial bonding strength --- joint concrete --- interface processing --- washed rough surface --- roughness --- storage time --- cement mortar --- End-of-Life Tyre --- waste --- surface treatment --- compressive strength --- flexural strength --- workability --- fly ash --- freezing shaft sinking --- shaft lining structure --- uneven pressure --- hybrid fiber-reinforced concrete --- crack --- autogenous self-healing --- curing conditions --- supplementary cementitious materials (SCMs) --- GRC-PC --- integrated wall panels --- composite method --- shrinkage properties --- dissipation energy density --- high-strength concrete --- Weibull distribution --- damage mechanics --- constitutive model --- repeated impact --- ACI 544-2R --- high temperatures --- fire --- residual strength --- lime-cement mortar --- air-entrained agent --- heritage conservation --- reconstruction and restoration of historical buildings --- properties --- mechanical --- electrical resistivity --- ecofriendly ternary concrete --- SCBA --- SF --- coastal cemented soil --- nano silica --- iron tailings --- mechanical properties --- microscopic mechanism --- granite dust --- stabilizer --- particle size --- plasticity --- unconfined compression strength --- cement --- lime --- sustainable materials --- fibre-reinforced composite --- recycled aggregates

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Soil erosion by wind is significant to Earth systems and human health. There is a strong interest in understanding the factors and processes of soil erosion by wind as well as in developing and applying methods to control dust emission from soils and to stabilize active sands. The Special Issue contains information on applications of natural and synthetic materials to reduce soil erosion, development of materials and methods, experimental methods and modeling, impacts on the soil quality and the environments, and quantification of the efficiency in dust control and sand stabilization applications.

wind erosion --- dust --- suppressants --- PM10 --- wind tunnel --- lignin --- resin --- bitumen --- PVA --- brine --- direct shear test --- post-harvest waste --- Chinese Loess Plateau --- optimal dosage --- prevailing wind --- sand transport --- Hobq Desert --- Yellow River --- dune stabilization --- restoration --- coastal dune --- vegetation removal --- multi-taxa --- biodiversity --- LTER --- temporal dynamics --- shrub encroachment --- loess --- metakaolin --- dust control --- geopolymer --- soil erosion --- global carbon budget --- soil organic carbon erosion --- deposition --- gaseous emissions --- enrichment ratio --- soil depletion --- preferential removal --- microbial-induced calcite precipitation --- desert soil --- biostimulation --- erosion mitigation --- surface shear stress --- isolated dune --- bridge --- aeolian processes --- arid areas --- dust emission --- dust sources --- environmental pollution --- infrastructures --- human activities --- particle size distribution --- polymers --- sand dune --- soil quality

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Cement and lime currently are the most common binders in building materials. However, alternative materials and methods are needed to overcome the functional limitations and environmental footprint of conventional products. This Special Issue dedicated to “New frontiers in cementitious and lime-based materials and composites” gathers selected reviews and experimental articles that showcase the most recent trends in this multidisciplinary field. Authoritative contributions from all around the world provide important insights into all areas of research related to cementitious and lime-based materials and composites, spanning from structural engineering to geotechnics, including materials science and processing technology. This Topical Collection is intended to foster innovation and help researchers and developers to identify new solutions for a more sustainable and functional built environment.

Technology: general issues --- History of engineering & technology --- durability --- hardened properties --- green composite --- fresh properties --- recycled concrete aggregates --- natural coarse aggregates --- enzyme-induced calcite precipitation --- microbial-induced calcite precipitation --- geotechnical engineering --- geoenvironmental engineering --- precast concrete wall --- interfacial bonding strength --- joint concrete --- interface processing --- washed rough surface --- roughness --- storage time --- cement mortar --- End-of-Life Tyre --- waste --- surface treatment --- compressive strength --- flexural strength --- workability --- fly ash --- freezing shaft sinking --- shaft lining structure --- uneven pressure --- hybrid fiber-reinforced concrete --- crack --- autogenous self-healing --- curing conditions --- supplementary cementitious materials (SCMs) --- GRC-PC --- integrated wall panels --- composite method --- shrinkage properties --- dissipation energy density --- high-strength concrete --- Weibull distribution --- damage mechanics --- constitutive model --- repeated impact --- ACI 544-2R --- high temperatures --- fire --- residual strength --- lime-cement mortar --- air-entrained agent --- heritage conservation --- reconstruction and restoration of historical buildings --- properties --- mechanical --- electrical resistivity --- ecofriendly ternary concrete --- SCBA --- SF --- coastal cemented soil --- nano silica --- iron tailings --- mechanical properties --- microscopic mechanism --- granite dust --- stabilizer --- particle size --- plasticity --- unconfined compression strength --- cement --- lime --- sustainable materials --- fibre-reinforced composite --- recycled aggregates

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For at least six hundred million years, life has been a fascinating laboratory of crystallization, referred to as biomineralization. During this huge lapse of time, many organisms from diverse phyla have developed the capability to precipitate various types of minerals, exploring distinctive pathways for building sophisticated structural architectures for different purposes. The Darwinian exploration was performed by trial and error, but the success in terms of complexity and efficiency is evident. Understanding the strategies that those organisms employ for regulating the nucleation, growth, and assembly of nanocrystals to build these sophisticated devices is an intellectual challenge and a source of inspiration in fields as diverse as materials science, nanotechnology, and biomedicine. However, “Biological Crystallization” is a broader topic that includes biomineralization, but also the laboratory crystallization of biological compounds such as macromolecules, carbohydrates, or lipids, and the synthesis and fabrication of biomimetic materials by different routes. This Special Issue collects 15 contributions ranging from biological and biomimetic crystallization of calcium carbonate, calcium phosphate, and silica-carbonate self-assembled materials to the crystallization of biological macromolecules. Special attention has been paid to the fundamental phenomena of crystallization (nucleation and growth), and the applications of the crystals in biomedicine, environment, and materials science.

chitosan --- Csep1p --- bond selection during protein crystallization --- bioremediation --- education --- reductants --- heavy metals --- biomimetic crystallization --- MTT assay --- protein crystallization --- drug discovery --- optimization --- polymyxin resistance --- lysozyme --- ependymin-related protein (EPDR) --- equilibration between crystal bond and destructive energies --- barium carbonate --- dyes --- microseed matrix screening --- nanoapatites --- colistin resistance --- Haloalkane dehalogenase --- diffusion --- polyacrylic acid --- random microseeding --- protein ‘affinity’ to water --- insulin --- protein crystal nucleation --- agarose --- lithium ions --- ependymin (EPN) --- {00.1} calcite --- seeding --- Campylobacter consisus --- metallothioneins --- Crohn’s disease --- balance between crystal bond energy and destructive surface energies --- color change --- microbially induced calcite precipitation (MICP) --- crystallization of macromolecules --- crystallization --- calcein --- MCR-1 --- Cry protein crystals --- L-tryptophan --- circular dichroism --- crystal violet --- nanocomposites --- halide-binding site --- calcium carbonate --- PCDA --- ultrasonic irradiation --- adsorption --- biochemical aspects of the protein crystal nucleation --- GTL-16 cells --- proteinase k --- neutron protein crystallography --- classical and two-step crystal nucleation mechanisms --- thermodynamic and energetic approach --- heavy metal contamination --- N-acetyl-D-glucosamine --- crystallization in solution flow --- solubility --- biomorphs --- droplet array --- biomimetic materials --- ferritin --- biomineralization --- wastewater treatment --- H3O+ --- silica --- graphene --- supersaturation dependence of the crystal nucleus size --- pyrrole --- micro-crystals --- nucleation --- crystallography --- mammalian ependymin-related protein (MERP) --- high-throughput --- vaterite transformation --- gradients --- materials science --- bioprecipitation --- biomedicine --- human carbonic anhydrase IX --- protein crystal nucleation in pores --- growth --- crystal growth