«ÉÏһƪ/Previous Article|±¾ÆÚĿ¼/Table of Contents|ÏÂһƪ/Next Article»

Öйú²ÄÁϽøÕ¹[ISSN:1674-3962/CN:61-1473/TG]

¾í:

ÆÚÊý:

2018ÄêµÚ04ÆÚ

Ò³Âë:

057-63

À¸Ä¿:

Ç°ÑØ×ÛÊö

³ö°æÈÕÆÚ:

2018-04-30

ÎÄÕÂÐÅÏ¢/Info

Title:

Key Material Genome of Titanium Alloys and Application of High Throughput Experiment and Computation

×÷Õß:

ËïÇÉÑÞ1; ¶ÅÓÂ2; ÁõÁ¢±ó2; ºúÇàÃç3; Ð¤ÁÖ1; Ëï¾ü1

1.Î÷°²½»Í¨´óѧ ½ðÊô²ÄÁÏÇ¿¶È¹ú¼ÒÖصãʵÑéÊÒ£¬ÉÂÎ÷ Î÷°² 710049 2.ÖÐÄÏ´óѧ ·ÛÄ©Ò±½ð¹ú¼ÒÖصãʵÑéÊÒ£¬ºþÄÏ ³¤É³ 410083 3.Öйú¿ÆѧԺ½ðÊôÑо¿Ëù ÉòÑô²ÄÁÏ¿Æѧ¹ú¼ÒʵÑéÊÒ£¬ÁÉÄþ ÉòÑô 110016

Author(s):

SUN Qiaoyan1;  DU Yong2;  LIU Libin2;  HU Qingmiao3;  XIAO Lin1;  SUN Jun1

1.State Key Laboratory for Mechanical Behavior of Materials, Xi¡¯an Jiaotong University, Xi¡¯an 710049, China 2.State Key Laboratory for Powder Metallurgy, Central South University, Changsha 410083, China 3.Institute of Metal Research, Chinese Academy of Sciences, Shenyang National Laboratory for Materials Science, Shenyang 110016, China

¹Ø¼ü´Ê:

îѺϽð; ¸ßͨÁ¿ÊµÑéÓë¼ÆËã; Î¢¹Û×éÖ¯; Á¦Ñ§ÐÔÄÜ; ²ÄÁÏ»ùÒò

Keywords:

titanium alloys;  high throughput experiments and computation;  microstructure;  mechanical properties;  materials genome

DOI:

10.7502/j.issn.1674-3962.2018.04.07

ÎÄÏ×±êÖ¾Âë:

A

ÕªÒª:

¼Ó¿ì¸ßÐÔÄÜîѺϽðµÄÑз¢Ëٶȡ¢½µµÍÑз¢³É±¾¶ÔÎÒ¹ú¸ß¶Ë×°±¸ÖÆÔìÖÁ¹ØÖØÒª¡£×÷Ϊ¹Ø¼ü½á¹¹²ÄÁÏ£¬Ç¿¶È¡¢ËÜÐÔÓëÈÍÐÔÊDZ£ÕÏîѺϽ𹹼þ°²È«ÔËÐеĹؼüÁ¦Ñ§ÐÔÄÜÖ¸±ê¡£Í¨¹ý¸ßͨÁ¿¼ÆËã¿ÉÔ¤²âºÏ½ðµÄÄ£Á¿¡¢±ÈÈÈ¡¢ÈÈÅòÕÍϵÊýµÈ¶àÖÖÎïÀíÐÔÄÜÖ¸±ê£¬µ«ÊǶÔÓÚÇ¿¶È¡¢ËÜÐÔÓëÈÍÐÔµÈÁ¦Ñ§ÐÔÄÜÖ¸±êÉÐȱÉÙÔ¤²âÄ£Ðͺ͹«Ê½£¬Ô­ÒòÊÇÁ¦Ñ§ÐÔÄܼä½ÓÒÀÀµºÏ½ðµÄ»¯Ñ§³É·Ö£¬Ö±½ÓÓ°ÏìÁ¦Ñ§ÐÔÄܵÄÒòËØÊǺϽðµÄ΢¹Û×éÖ¯¡£¸ßÐÔÄÜîѺϽðµÄ¹Ø¼ü¡°»ùÒò¡±Êdzɷ֡¢Ïà/×éÖ¯½á¹¹Ó뾧ÌåȱÏÝ¡£¸ßͨÁ¿¼ÆËãºÍÀ©É¢¶àÔª½Ú½¨Á¢ºÏ½ð³É·ÖÓëÏàµÄ¶ÔÓ¦¹Øϵ£¬Ïೡ¶¯Á¦Ñ§¼ÆËãÓëÄ£ÄâʵÏÖ¶ÔÏàÓë΢¹Û×éÖ¯ÑÝ»¯µÄÔ¤²â£¬Í¨¹ý΢Äɳ߶ÈÁ¦Ñ§ÐÔÄܲâÊÔ¼¼Êõ»ñµÃ΢¹Û×éÖ¯½á¹¹µÄÁ¦Ñ§ÐÔÄÜÊý¾Ý¡£ÆÚÍûͨ¹ýÒÔÉϸ÷»·½ÚÑо¿½á¹ûÓëÊý¾ÝµÄÓлúÕûºÏ£¬½¨Á¢îѺϽð³É·Ö¡¢ÏàÓë΢¹Û×éÖ¯¡¢Á¦Ñ§ÐÔÄÜÊý¾Ý¿â£¬ÓÐÖúÓÚÌáÉý¸ßÐÔÄÜîѺϽðµÄÑз¢Ëٶȣ¬Âú×ãÎÒ¹ú¹Ø¼ü¼¼ÊõÁìÓò¶ÔÏȽøîѺϽðµÄÐèÇó¡£

Abstract:

To accelerate researching newª²type titanium alloys with improved mechanical properties and to lower cost at the same time are very important for the advanced equipments of our country. As structural material, strength, ductility and toughness are key factors for performance of structural parts. Some physical properties, such as elastic modulus, heat conductivity, diffusion coefficient, thermal expansion coefficient and specific heat, have been calculated or measured with highª²throughput computation and experiments. However, mechanical properties, such as strength, ductility and toughness, cannot be calculated with computational methods due to lack of models and enough data. The mechanical properties are much more dependent on microstructures than compositions. Therefore, the key genes for advanced titanium alloys are compositions, phases/microstructures and defects of crystals. The relationship between chemical composition and phase can be founded with firstª²principles calculation, and dependence of phase on composition can be measured with diffusionª²multiple approach efficiently. Microstructural evolution can be predicted with phaseª²field models. The mechanical properties of individual unit of microstructures can be measured with nanoª²mechanical methods, such as nano indentation and compressive or tensile methods. The above results and data should be integrated into database for titanium alloys and be used to accelerate researching newª²type titanium alloys to meet great needs of advanced titanium alloys in key industrial fields of our country.

³£Óù¦ÄÜ

¸üÐÂÈÕÆÚ/Last Update: 2018-05-08