- D A Parshin, “Examples of controlling the technological stress state characteristics of layer-by-layer manufactured products in the framework of the accreted solid model”, J. Phys.: Conf. Ser., 1902, no. 1, 2021, 012019
- Pavel Kuznetcov, Anton Zhukov, Artem Deev, Vitaliy Bobyr, Mikhail Staritcyn, Additive Manufacturing of High-performance Metals and Alloys - Modeling and Optimization, 2018
- Dmitriy Parshin, PROBLEMS OF APPLIED MECHANICS, 2020, 131
- K E Kazakov, D A Parshin, “A model of mechanics of growing solids for the stress-strain analysis of wound composites reinforced with thin unidirectional fibers”, J. Phys.: Conf. Ser., 2231, no. 1, 2022, 012006
- N. E. Stadnik, E. V. Murashkin, E. P. Dats, 2133, CENTRAL EUROPEAN SYMPOSIUM ON THERMOPHYSICS 2019 (CEST), 2019, 380013
- Xiaoshuang Liu, Yuxiao Zou, Yingxuan Wu, Dong Cui, Xiaobao Zuo, 48, Smart & Sustainable Infrastructure: Building a Greener Tomorrow, 2024, 233
- Jean-François Ganghoffer, Ibrahim Goda, “A combined accretion and surface growth model in the framework of irreversible thermodynamics”, International Journal of Engineering Science, 127, 2018, 53
- D A Parshin, “Nonclassical mathematical model for the mechanical analysis of additive manufacturing viscoelastic materials on rotating cylindrical substrates”, J. Phys.: Conf. Ser., 1205, 2019, 012044
- P S Bychkov, A V Chentsov, V M Kozintsev, A L Popov, “Determination of residual stresses in objects at their additive manufacturing by layer-by-layer photopolymerization method”, J. Phys.: Conf. Ser., 991, 2018, 012016
- A Romanov, “A spring system method for a mesh generation problem”, J. Phys.: Conf. Ser., 991, 2018, 012068