Crossref Citations
This article has been cited by the following publications. This list is generated based on data provided by
Crossref.
Hsueh, Chun-Hway
and
Lu, Mei-Chien
1989.
Elastic stress transfer from fiber to coating in a fiber-coating system.
Materials Science and Engineering: A,
Vol. 117,
Issue. ,
p.
115.
Hsueh, Chun-Hway
1990.
Effects of interfacial bonding on sliding phenomena during compressive loading of an embedded fibre.
Journal of Materials Science,
Vol. 25,
Issue. 9,
p.
4080.
Weihs, Timothy P.
and
Nix, William D.
1991.
Experimental Examination of the Push‐Down Technique for Measuring the Sliding Resistance of Silicon Carbide Fibers in a Ceramic Matrix.
Journal of the American Ceramic Society,
Vol. 74,
Issue. 3,
p.
524.
Hsueh, Chun-Hway
1991.
Interfacial debonding and fiber pull-out stresses of fiber-reinforced composites III: With residual radial and axial stresses.
Materials Science and Engineering: A,
Vol. 145,
Issue. 2,
p.
135.
Koss, D. A.
Kallas, M. N.
and
Hellmann, J. R.
1992.
Mechanics of Interfacial Failure during Thin-Slice Fiber Pushout Tests.
MRS Proceedings,
Vol. 273,
Issue. ,
Ferber, M.K.
Wereszczak, A.A.
Hansen, D.H.
and
Homeny, J.
1993.
Evaluation of interfacial mechanical properties in SiC fiber-reinforced macro-defect-free cement composites.
Composites Science and Technology,
Vol. 49,
Issue. 1,
p.
23.
Chun-Hway Hsueh
1993.
Interfacial debonding and fiber pull-out stresses of fiber-reinforced composites IX: A simple treatment of Poisson's effect for frictional interfaces.
Materials Science and Engineering: A,
Vol. 161,
Issue. 1,
p.
L1.
Hsueh, Chun-Hway
1993.
Analyses of slice compression tests for aligned ceramic matrix composites.
Acta Metallurgica et Materialia,
Vol. 41,
Issue. 12,
p.
3585.
Hsueh, C. H.
and
Ferber, M. K.
1993.
Evaluations of residual axial stresses and interfacial friction in Nicalon fibre-reinforced macro-defect-free cement composites.
Journal of Materials Science,
Vol. 28,
Issue. 9,
p.
2551.
Lawrence, C. W.
Briggs, G. A. D.
Scruby, C. B.
and
Davies, J. R. R.
1993.
Acoustic microscopy of ceramic-fibre composites.
Journal of Materials Science,
Vol. 28,
Issue. 13,
p.
3635.
Hsueh, Chun‐Hway
1993.
Evaluation of Interfacial Properties of Fiber‐Reinforced Ceramic Composites Using a Mechanical Properties Microprobe.
Journal of the American Ceramic Society,
Vol. 76,
Issue. 12,
p.
3041.
Hsueh, C. H.
Ferber, M. K.
and
Wereszczak, A. A.
1993.
The relative residual fibre displacement after indentation loading and unloading of fibre-reinforced ceramic composites.
Journal of Materials Science,
Vol. 28,
Issue. 8,
p.
2227.
Hsueh, Chun-Hway
1994.
Slice Compression Tests Versus Fiber Push-In Tests.
Journal of Composite Materials,
Vol. 28,
Issue. 7,
p.
638.
Marshall, D.B.
Shaw, M.C.
and
Morris, W.L.
1995.
The determination of interfacial properties from fiber sliding experiments: The roles of misfit anistropy and interfacial roughness.
Acta Metallurgica et Materialia,
Vol. 43,
Issue. 5,
p.
2041.
Lara-Curzio, E.
and
Ferber, M. K.
1996.
Numerical Analysis and Modelling of Composite Materials.
p.
357.
Zhou, X.-F
Wagner, H.D
and
Nutt, S.R
2001.
Interfacial properties of polymer composites measured by push-out and fragmentation tests.
Composites Part A: Applied Science and Manufacturing,
Vol. 32,
Issue. 11,
p.
1543.
Yang, Yingchao
Liang, Xin
Chen, Weibing
Cao, Linlin
Li, Minglin
Sheldon, Brian W.
and
Lou, Jun
2015.
Quantification and promotion of interfacial interactions between carbon nanotubes and polymer derived ceramics.
Carbon,
Vol. 95,
Issue. ,
p.
964.
Liao, Mengyuan
Yang, Yuqiu
and
Hamada, Hiroyuki
2016.
Mechanical performance of glass woven fabric composite: Effect of different surface treatment agents.
Composites Part B: Engineering,
Vol. 86,
Issue. ,
p.
17.
Liang, Xin
Yang, Yingchao
Lou, Jun
and
Sheldon, Brian W.
2017.
The impact of core-shell nanotube structures on fracture in ceramic nanocomposites.
Acta Materialia,
Vol. 122,
Issue. ,
p.
82.
Al-Quraishi, Karrar K.
Wang, Min
Liang, Jia
Jia, Song
Kauppila, Wesley
Wang, Jing
and
Yang, Yingchao
2020.
Strengthening the interface between individual aramid fibers and polymer at room and elevated temperatures.
Materials Today Communications,
Vol. 24,
Issue. ,
p.
101254.