Editor in chief: Aleksandr Inozemtsev

Ph.D. in Technical Sciences, Associate Professor

Associate Professor at the Department of Construction Materials Science,
National Research Moscow State University of Civil Engineering (NRU MGSU).

Academic Secretary of Dissertation Council 24.2.339.01.

Contact email: editors@modern-construction.ru

 

WoS ResearcherID: K-6341-2013

Scopus AuthorID: 55889834500

ORCID: 0000-0001-7807-688X

RSCI AuthorID: 616006

Author of 150+ scholarly publications across various media, including:

45+ articles in leading peer-reviewed journals (Stroitelnye Materialy, Vestnik MGSU, Nanotechnologies in Construction, Industrial And Civil Engineering, etc.)

30+ international publications indexed in Scopus (Materials, Structural Concrete, Magazine of Civil Engineering, Advances in Cement Research, etc.)

5 invention patents and 1 monograph.


Hirsch Index (RSCI) – 17; Scopus – 8; Web of Science – 5.


Since 2006, has participated in various international and all-Russian scientific and practical conferences.  

Has over 19 years of experience in scientific and pedagogical activities. 


Key Scientific Results Over the Past 5 Years:  

- A methodology has been developed for calculating the composition of energy- and resource-efficient nanomodified composite materials with specified performance properties (compressive strength of at least 40 MPa, average density of no more than 1600 kg/m³). The selection of key components based on the regional mineral resource base for production in Russia has been scientifically justified.  
- A methodology has been developed for studying the structural parameters and construction-technological properties using highly informative research methods, such as differential thermal analysis, IR and Raman spectroscopy, NMR spectroscopy, X-ray tomography, optical microscopy, and rheometry.  
- The processes of cement stone structure formation in the presence of a nanoscale modifier containing iron (III) hydroxide sol and silicic acid sol have been studied.  
- The specific effects of various plasticizers on the workability of concrete mixtures containing both unmodified and nanomodified microspheres have been identified.  
- The influence of key formulation and technological factors on the average density and porosity of lightweight concrete with microspheres has been investigated.  
- Theoretical and experimental studies of energy- and resource-efficient nanomodified composite materials have been conducted, including research on the mechanical and deformation properties of the composite.  
- The patterns of influence of formulation and technological factors on the composition, structure, and set of properties have been established.  
- Based on percolation theory and fractal geometry, an analytical model of chaotic reinforcement has been developed, considering the geometric characteristics and physical properties of fibers.  
- The durability of composites made from regional materials has been assessed, taking into account the climatic conditions of the Western Pacific region, characteristic of Russian territories.  
- A techno-economic justification for the application of energy- and resource-efficient nanomodified composite materials has been conducted.  
- Technical requirements and proposals have been formulated for the development and production of products made from energy- and resource-efficient nanomodified composite materials derived from regional raw material resources, considering technological capabilities and the specificities of the real sector of the economy in Russia and/or Vietnam.