**1. Introduction**

94 Sintering of Ceramics – New Emerging Techniques

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[13] X. Jin, A. Chang, H. Zhang, D. Zhang, A Comparison Study of Sinterability and

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718.

properties of Cu-containing Mn1. 95-*x*Ni0. 45Co0. 15Cu0. 45Zn*x*O4 (0≤*x*≤0.3) NTC

microstructure and electrical properties of Mn1. 17-*x*Ni0. 93Co0. 9Zn*x*O4 (0≤*x*≤0.075)

of Mn0.43Ni0.9CuFe0.67O4 NTC Thermistor Materials by Pechini Method, Journal of

Electrical Properties for Microwave and Conventional Sintered Mn0.43Ni0.9CuFe0.67O4 Ceramics, Journal of Materials Science & Technology, 26

Mn0.43Ni0.9CuFe0.67O4 by a polymerized complex method, Materials Chemistry and

Evidence for the Microwave Effect During Hybrid Sintering, Journal of the

Mn0.43Ni0.90CuFe0.67O4 thermistor materials prepared by polymerized complex

Characters of the CoMnNiO-Based NTC Thermistor, Micronanoelectronic

sintering of electronic oxide ceramics, Journal of Inorganic Materials, 17(2002): 713-

This chapter mainly illustrates that the mechanism and process of cold-bonding technique as well as using of three various innocuous recycling resources, construction residual soil, granite sludge, and lime sludge, to produce recycling coarse aggregates through the coldbonding technique.
