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Conclusion Restoration of monuments is a large and complex systematic engineering, it needs to make comprehensive use of the social sciences, natural sciences, engineering science knowledge, with the advancement of science and technology and development of chemical industry, there will be more, newer and more effective chemical materials for cultural relics protection, chemical materials, chemical technology can have a broad prospect in the field of monuments restoration technology, the green chemistry materials can make the valuable historical and cultural heritage of mankind to be better protected.
Materials and Structures, 2007,40(7)
Journal of Cultural Economics, 2001,25(2)
Materials and Structures, 1997,30(8)
Journal of Adhesion Science and Technology, 2000, 14(2)

Experiment Materials.
Pandey, A review on the factors affecting the photocatalytic degradation of hazardous materials, Material Science and Engineering International Journal. 1(3) (2017) 106-114
Sustainable Materials and Technologies. 9 (2016) 10-40
Advances in Materials Science and Engineering. (2015) [40] M.N.
A review, Indian Journal of Materials Science. (2015)

This criterion is the generalization of Griffith’s classical model to describe the development of cracks in brittle materials.
Usually, a failure criterion is assumed to be a fixed, limiting stress condition that corresponds to ultimate failure of the material.
Procedia Earth and Planetary Science, 1(2009)1242-1246
International Journal of Rock Mechanics and Mining Sciences, 34(1998) 1165- 1186
International Journal of Rock Mechanics and Mining Sciences, 36(1999) 777-809

Magnetic mineral materials under strong sunshine will produce magnetic field and act on human body.
Materials and Method Sand Temperature Measuring System Used Outdoor and Indoor.
Acknowledgements National Natural Science Foundation of china (81160542, 81160458).
Foundation of Department of Science and Technology, Xinjiang Uygur Autonomous Region(201123113).
Kuerban: Chinese Journal Rehabil Theory Practice, Vol.11 (2005) No.5 (In Chinese)

Schmuki, Hydroxyapatite growth on anodic TiO2 nanotubes, Journal of Biomedical Materials Research Part A, Vol. 77A (2006) 534-541
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Chou, A novel bioactive porous CaSiO3 scaffold for bone tissue engineering, Journal of Biomedical Materials Research Part A, Vol. 76A (2006) 196–205

Such heterogeneities can be due to the constitutive material itself such as in the case of composite materials [5].
Industrial components of any shape can be directly used in this case, thus leading the identified parameters to be more representative of the actual response of in situ constitutive materials.
Ifju, Journal of Composite Materials, Vol. 35 (1999), pp. 797-821, Technomic [8] L.
Pierron, International Journal of Mechanical Sciences (2004), submitted
Pierron, Journal of Sound and vibrations (2004).

Methods and Materials Experimental material.
(in Chinese) [3] Haiou Wang, Haiyang Xu, Guangrong Zhong: Journal of Anhui Agicultual Science.
[6] Biao Li , Zhi Xiong , Fujun Miao: Advanced Materials Research.
Kemp: Australia Journal Agricultural Research.
Johns: Australia Journal Plant Physiology.

Materials diseases.
The unnatural materials degradation or the reduced materials quality are materials diseases in CFST arch bridge.
Figure6 is the photo of materials diseases in some bridge in Guangxi.
Figure 6 Materials diseases photo Environmental diseases.
Journal of Chongqing Jiaotong University (Natural Science).Vol.32,2013(sup.1),p.738-741,826.

Especially it concerns oxide ceramic materials, for example, ferrites.
Series: Materials Science and Engineering 81 (2015) 1-5
Wetzig, Ion Beams in Materials Processing and Analysis, Springer Verlag, Germany, 2013
Yatsui, Intense ion-beam treatment of materials, MRS Bulletin 21 (1996) 58–62
Cholakh, Ion Modification of Functional Materials, Ekaterinburg: GOU HPE URFU, 2014.

Journal Citation (to be inserted by the publisher) Copyright by Trans Tech Publications Porosity-Grading Porous Materials by Centrifugal Sintering Y.
Uchimura 2 1 National Institute of Advanced Industrial Technology and Science, Moriyama, Nagoya 463-8560, Japan, y.kinemuchi@aist.go.jp 2 Shinto V-Cerax, ltd., Honohara, Toyokawa 442-8506, Japan Keywords: Porous Materials, Centrifugal Force, Grading Material, Sintering Abstract.
The acceleration was generated by high-speed rotation of ceramics, which allows pressing materials gradually along the radius of rotation.
Among those technologies, it is widely accepted that specifically designed microstructures, on both the micro- and macro-scale, with designated pore diameter, porosity and specific surface area are the key to improving these materials' performance.
Under the centrifugal force, materials are subjected to pressure which gradually changes along the radial direction of rotation.