Idea of macro-scale and micro-scale prestressed ceramics

Junfeng Gu , Shuai Fu , Hang Ping , Wei Ji , Ji Zou , Hao Wang , Weimin Wang , Fan Zhang , Hanxing Liu , Zhengyi Fu

Interdisciplinary Materials ›› 2024, Vol. 3 ›› Issue (6) : 897 -906.

PDF (2451KB)
Interdisciplinary Materials ›› 2024, Vol. 3 ›› Issue (6) : 897 -906. DOI: 10.1002/idm2.12224
PERSPECTIVE

Idea of macro-scale and micro-scale prestressed ceramics

Author information +
History +
PDF (2451KB)

Abstract

The brittleness of ceramics restricts their engineering application. Prestressing is promising to solve the problem, yet still lacks enough attention and extensive investigation. This work proposes the idea of macro-scale and microscale prestressed ceramics: to form compressive prestress in macro- or microscale range in the ceramics by designed additional force, which offsets the fracture stress at the crack tips, then enhances the strength of ceramics. The macro-scale prestressed ceramic has a designed long-range ordering stress distribution in a large scale, similar to the reinforced concrete and tempered glass. The micro-scale ceramic has a designed short-range ordered stress distribution, similar to that in the natural biomaterials. Strategies constructing the macro-scale and micro-scale prestressed ceramics are planned. Future research interests and challenges are prospected for developing the mechanical properties of ceramics.

Keywords

macro-scale / micro-scale / prestressed ceramics / strength

Cite this article

Download citation ▾
Junfeng Gu, Shuai Fu, Hang Ping, Wei Ji, Ji Zou, Hao Wang, Weimin Wang, Fan Zhang, Hanxing Liu, Zhengyi Fu. Idea of macro-scale and micro-scale prestressed ceramics. Interdisciplinary Materials, 2024, 3(6): 897-906 DOI:10.1002/idm2.12224

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Kingery WD, Bowen HK, Uhlmann DR. Introduction to ceramics. John Wiley &Sons;1976:581.
[2]

Ritchie RO. The conflicts between strength and toughness. Nat Mater. 2011;10(11):817-822.
[3]

Suryanarayana C. Nanocrystalline materials. Int Mater Rev. 1995;40:41-64.
[4]

Yamada S, Hirao K, Yamauchi Y, Kanzaki S. High strength B4C-TiB2 composites fabricated by reaction hot-pressing. J Eur Ceram Soc. 2003;23(7):1123-1130.
[5]

Marshall DB, Oliver WC. Measurement of interfacial mechanical properties in fiber-reinforced ceramic composites. J Am Ceram Soc. 1987;70(8):542-548.
[6]

Heuer AH. Transformation toughening in ZrO2-containing ceramics. J Am Ceram Soc. 1987;70(10):689-698.
[7]

Zhang J, Liu G, Cui W, et al. Plastic deformation in silicon nitride ceramics via bond switching at coherent interfaces. Science. 2022;378:371-376.
[8]

Johnston RD, Chipman RD, Knapp WJ. Prestressed ceramics as a structural material. J Am Ceram Soc. 1953;36(4):121-126.
[9]

Shanley FR, Knapp WJ. Ceramics as structural materials. J Struct Div. 1965;91(4):47-56.
[10]

Knapp WJ, Kurtz PJ, Shanley FR. An investigation of ceramics as structural materials (NASA-CR-632). NASA;1966.
[11]

Brackett RL, Felton LP, Shanley FR. Geometric properties of a prestressed segmented spherical shell (REPT-68-23). NASA;1968.
[12]

Bush EA, Hummel FA. High-temperature mechanical properties of ceramic materials: III, vitrified chemical and refractory porcelain. Am Ceram Soc Bull. 1961;40(5):310-313.
[13]

Smoke EJ, Illyn AV, Koenig JH. The effect of thermal conditioning on high frequency ceramic dielectric insulation. Natl Acad Sci-Natl Res Counc Publ. 1955;396:34-36.
[14]

Gravley CK. Prestressed dielectric ceramic bodies. US Patent 2,972, 176. February 21, 1961.
[15]

Insley RH, Barczak VJ. Thermal conditioning of polycrystalline alumina ceramics. J Am Ceram Soc. 1964;47(1):1-4.
[16]

Kirchner HP, Walker RE, Platts DR. Strengthening alumina by quenching in various media. J Appl Phys. 1971;42(10):3685-3692.
[17]

Kirchner HP, Gruver RM, Walker RE. Strengthening of hot-pressed Al2O3 by quenching. J Am Ceram Soc. 1973;56(1):17-21.
[18]

Kirchner HP, Gruver RM. The elevated temperature flexural strength and impact resistance of alumina ceramics strengthened by quenching. Mater Sci Eng. 1974;13(1):63-69.
[19]

Buessem WR, Gruver RM. Computation of residual stresses in quenched Al2O3. J Am Ceram Soc. 1972;55(2):101-104.
[20]

Nordberg ME, Mochel EL, Garfinkel HM, Olcott JS. Strengthening by ion exchange. J Am Ceram Soc. 1964;47(5):215-219.
[21]

Kistler SS. Stresses in glass produced by nonuniform exchange of monovalent ions. J Am Ceram Soc. 1962;45:59-68.
[22]

Kirchner HP, Gruver RM. Chemical strengthening of polycrystalline ceramics. J Am Ceram Soc. 1966;49(6):330-333.
[23]

Shockey DA, Marchand AH, Skaggs SR, Cort GE, Burkett MW, Parker R. Failure phenomenology of confined ceramic targets and impacting rods. Int J Impact Eng. 1990;9(3):263-275.
[24]

Anderson CE, Royal-Timmons SA. Ballistic performance of confined 99.5%-Al2O3 ceramic tiles. Int J Impact Eng. 1997;19(8):703-713.
[25]

Camacho GT, Ortiz M. Computational modelling of impact damage in brittle materials. Int J Solids Struct. 1996;33(20):2899-2938.
[26]

Anderson CE, Morris BL. The ballistic performance of confined Al2O3 ceramic tiles. Int J Impact Eng. 1992;12(2):167-187.
[27]

Bao Y, Su S, Yang J, Fan Q. Prestressed ceramics and improvement of impact resistance. Mater Lett. 2002;57(2):518-524.
[28]

Pickering EG, O’Masta MR, Wadley HNG, Deshpande VS. Effect of confinement on the static and dynamic indentation response of model ceramic and cermet materials. Int J Impact Eng. 2017;110:123-137.
[29]

Hazell PJ, Wang H, Lin T, et al. On the improvement of the ballistic performance of a silicon carbide tile through pre-stress: experiments and simulations. Int J Impact Eng. 2021;151:103836.
[30]

Hogan JD, Farbaniec L, Shaeffer M, Ramesh KT. The effects of microstructure and confinement on the compressive fragmentation of an advanced ceramic. J Am Ceram Soc. 2015;98:902-912.
[31]

Zhang R, Han B, Lu TJ. Confinement effects on compressive and ballistic performance of ceramics: a review. Int Mater Rev. 2021;66(5):287-312.
[32]

Bao Y, Kuang F, Sun Y, et al. A simple way to make pre-stressed ceramics with high strength. J Materiomics. 2019;5(4):657-662.
[33]

Sun Y, Wu T, Bao Y, et al. Preparation and strengthening mechanism of prestressed ceramic tile components. Int J Appl Ceram Technol. 2022;19(1):604-611.
[34]

Wei H, Li Y, Sun Y, Li K, Bao Y, Wan D. A novel prestress strategy to improve thermal shock resistance of bone China body. J Aust Ceram Soc. 2024;60:619-628.
[35]

Inglis CE. Stresses in a plate due to the presence of cracks and sharp corners. Trans Inst Naval Archit. 1913;55:219-241.
[36]

Ping H, Wagermaier W, Horbelt N, et al. Mineralization generates megapascal contractile stresses in collagen fibrils. Science. 2022;376:188-192.
[37]

Polishchuk I, Bracha AA, Bloch L, et al. Coherently aligned nanoparticles within a biogenic single crystal: a biological prestressing strategy. Science. 2017;358:1294-1298.
[38]

Duffy DM. Coherent nanoparticles in calcite. Science. 2017;358:1254-1255.
[39]

Meng YF, Zhu YB, Zhou LC, et al. Artificial nacre with high toughness amplification factor: residual stress-engineering sparks enhanced extrinsic toughening mechanisms. Adv Mater. 2022;34(9):2108267.
[40]

Zhu C, Wang Q, Zhu Y, et al. Nacre-inspired boron nitride/sodium alginate composite with enhanced mechanical properties by prestress. Composites, Part A. 2023;175:107796.
[41]

Xiong S, Liu J, Cao J, et al. 3D printing of crack-free dense polymer-derived ceramic monoliths and lattice skeletons with improved thickness and mechanical performance. Additive Manufact. 2022;57:102964.
[42]

Xu H, Zou J, Crookes R, et al. Enhanced properties of nanocrystalline alumina ceramic with compressive prestress and coherently aligned nanograins. J Am Ceram Soc. 2024;107:1949-1958.

RIGHTS & PERMISSIONS

2024 The Author(s). Interdisciplinary Materials published by Wuhan University of Technology and John Wiley & Sons Australia, Ltd.

AI Summary AI Mindmap
PDF (2451KB)

220

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/