潘路軍

1988年於西安交通大學電氣工程系電氣絕緣技術專業本科畢業；1994年赴日本大阪府立大學工學部電子物理專業留學。2000年獲博士學位並留校擔任助理教授，其間兼任日本科學技術振興機構（JST）及日本新能源和產業技術綜合開發機構（nedo）研究員； 2007年底回國工作，被大連理工大學聘為教授。
社會兼職：

潘路軍 - 研究領域（研究課題） ：
以碳納米管為代表的碳納米材料及器件以其納米級的尺寸、極穩定的物理和化學特性、優異的電性能和機械性能，在電子、化工、材料、紡織、機械、能源、環境、醫藥、生物等各大重要領域都具有廣闊的套用前景，必將在這些領域中發揮出越來越巨大的作用。本研究即是以碳納米管、碳納米線圈為主要研究對象，以化學氣相沉積法（CVD）製備單壁及多壁碳納米管及碳納米線圈，研究其特性並以此為基礎開發出具有新型功能的電子元器件及複合材料。

1）碳納米線圈的高效製備及其物理特性的研究
2）碳納米管垂直快速成長機理的研究
3）垂直配列碳納米管陣列的光傳導特性的研究
4）碳納米管和碳納米線圈的場發射特性及其在顯示器及照明等套用的研究
5）碳納米材料的大量製備及其在電磁波吸收特性的研究

1）フィールドエミッションディスプレイ技術（場發射型顯示器技術），日本CMC出版社, 2004年6月。
2）ディスプレイと機能性色素（顯示器和機能色素），日本CMC出版社, 2004年9月。
3）ナノカーボンハンドブック（碳納米材料手冊），日本NTS出版社, 2007年7月

1）M. Zhang, L. J. Pan, T. Miyazaki, and Y. Nakayama, Japanese Journal of Applied Physics Part 1-Regular Papers Short Notes & Review Papers 36, 4897-4900 (1997).
2）L. J. Pan, M. Zhang, and Y. Nakayama, Journal of Chemical Physics 110, 10509-10513 (1999).
3）L. J. Pan, M. Zhang, and Y. Nakayama, Chemistry of Materials 11, 1326-1330 (1999).
4）M. Zhang, Y. Nakayama, and L. J. Pan, Japanese Journal of Applied Physics Part 2-Letters 39, L1242-L1244 (2000).
5）T. Fujii, L. J. Pan, and Y. Nakayama, Japanese Journal of Applied Physics Part 1-Regular Papers Short Notes & Review Papers 39, 3627-3630 (2000).
6）M. Zhang, L. Pan, and Y. Nakayama, Journal of Non-Crystalline Solids 266, 815-820 (2000).
7）L. J. Pan, M. Zhang, and Y. Nakayama, Japanese Journal of Applied Physics Part 1-Regular Papers Short Notes & Review Papers 39, 1378-1381 (2000).
8）L. J. Pan, T. Hayashida, M. Zhang, and Y. Nakayama, Japanese Journal of Applied Physics Part 2-Letters 40, L235-L237 (2001).
9）S. Matsumoto, L. Pan, H. Tokumoto, and Y. Nakayama, Physica B-Condensed Matter 323, 275-276 (2002).
10）L. J. Pan, T. Hayashida, A. Harada, and Y. Nakayama, Physica B-Condensed Matter 323, 350-351 (2002).
11）T. Hayashida, L. Pan, and Y. Nakayama, Physica B-Condensed Matter 323, 352-353 (2002).
12）L. J. Pan, M. Zhang, and Y. Nakayama, Journal of Applied Physics 91, 10058-10061 (2002).
13）L. J. Pan, T. Hayashida, and Y. Nakayama, Journal of Materials Research 17, 145-148 (2002).
14）X. Q. Chen, S. L. Zhang, D. A. Dikin, W. Q. Ding, R. S. Ruoff, L. J. Pan, and Y. Nakayama, Nano Letters 3, 1299-1304 (2003).
15）K. Nishimura, L. Pan, and Y. Nakayama, Japanese Journal of Applied Physics Part 1-Regular Papers Short Notes & Review Papers 43, 5665-5666 (2004).
16）L. J. Pan, Y. Nakayama, H. Shiozaki, and C. Inazumi, Journal of Materials Research 19, 1803-1807 (2004).
17）K. Nishimura, N.OKAZAKI, L. J. Pan, and Y. Nakayama, Japanese Journal of Applied Physics Part 2-Letters & Express Letters 43, L471-L474 (2004).
18）H. Tanaka, S. Akita, L. J. Pan, and Y. Nakayama, Japanese Journal of Applied Physics Part 1-Regular Papers Short Notes & Review Papers 43, 1651-1654 (2004).
19）H. Tanaka, S. Akita, L. Pan, and Y. Nakayama, Japanese Journal of Applied Physics Part 2-Letters 43, L427-L429 (2004).
20）H. Tanaka, S. Akita, L. Pan, and Y. Nakayama, Japanese Journal of Applied Physics Part 1-Regular Papers Short Notes & Review Papers 43, 864-867 (2004).
21）H. Tanaka, S. Akita, L. J. Pan, and Y. Nakayama, Japanese Journal of Applied Physics Part 2-Letters 43, L197-L199 (2004).
22）G. Takeda, L. Pan, S. Akita, and Y. Nakayama, Japanese Journal of Applied Physics Part 1-Regular Papers Brief Communications & Review Papers 44, 5642-5645 (2005).
23）Y.KONISHI, S. Hokushin, H. Tanaka, L. J. Pan, S. Akita, and Y. Nakayama, Japanese Journal of Applied Physics Part 1-Regular Papers Short Notes & Review Papers 44, 1648-1651 (2005).
24）L. Pan, O. Konishi, H. Tanaka, O. Suekane, T. Nosaka, and Y. Nakayama, Japanese Journal of Applied Physics Part 1-Regular Papers Short Notes & Review Papers 44, 1652-1654 (2005).
25）S. Chakrabarti, T. Nagasaka, Y. Yoshikawa, L. J. Pan, and Y. Nakayama, Japanese Journal of Applied Physics Part 2-Letters & Express Letters 45, L720-L722 (2006).
26）Y. Nakayama, L. J. Pan, and G. Takeda, Japanese Journal of Applied Physics Part 1-Regular Papers Brief Communications & Review Papers 45, 369-371 (2006).
27）L. Pan, Y. Konishi, H. Tanaka, S. Chakrabarti, S. Hokushin, S. Akita, and Y. Nakayama, Journal of Vacuum Science & Technology B 25, 1581-1583 (2007).
28）S. Hokushin, L. Pan, and Y. Nakayama, Japanese Journal of Applied Physics Part 1-Regular Papers Brief Communications & Review Papers 46, 5383-5385 (2007).
29）S. Hokushin, L. Pan, Y. Konishi, H. Tanaka, and Y. Nakayama, Japanese Journal of Applied Physics Part 2-Letters & Express Letters 46, L565-L567 (2007).
30）S. Chakrabarti, L. Pan, H. Tanaka, S. Hokushin, and Y. Nakayama, Japanese Journal of Applied Physics Part 1-Regular Papers Brief Communications & Review Papers 46, 4364-4369 (2007).
31）L. Pan, T. Shoji, A. Nagataki, and Y. Nakayama, Advanced Engineering Materials 9, 584-587 (2007).
32）R. Tomokane, Y. Fujiyama, K. Tanaka, S. Akita, Y. Higashi, L. Pan, T. Nosaka, and Y. Nakayama, Japanese Journal of Applied Physics Part 1-Regular Papers Brief Communications & Review Papers 46, 1815-1817 (2007).
33）S. Chakrabarti, H. Kume, L. J. Pan, T. Nagasaka, and Y. Nakayama, Journal of Physical Chemistry C 111, 1929-1934 (2007).
34）R. Kanada, L. Pan, S. Akita, N. Okazaki, K. Hirahara and Y. Nakayama, Synthesis of multiwalled carbon nanocoils using co-deposited thin film of Fe-Sn as a precursor of the catalyst, Jpn. J. Appl. Phys. 1949–1951 (2008).
35）Y. Fujiyama, R. Tomokane, K. Tanaka, S. Akita, Y. Higashi, L. Pan, T. Nosaka, and Y. Nakayama, Alignment of Carbon Nanocoils in Polymer Matrix Using Dielectrophoresis, Jpn. J. Appl. Phys. 1991–1993 (2008).
36) M. Yamaguchi, L. Pan, S. Akita, and Y. Nakayama, Effect of ResidualacetyleneGas on Growth of Vertically Aligned Carbon Nanotubes, Jpn. J. Appl. Phys. 1937–1940(2008).

主要研究的領域為納米材料的製備及其物理特性的研究，至今已在國際會議和刊物上發表論文100餘篇，其中在重要國際SCI刊物上發表論文近40篇，申請和取得了納米材料的製備及場發射方面的日本及國際專利20餘項。自2000年發明了大量製備碳納米線圈的方法後，一直致力於碳納米線圈和碳納米管的製備控制和其電特性及機械特性方面的研究，積累了碳納米材料製備的關鍵技術和大量實際經驗。承擔了多項JST和NEDO的日本國家重點項目，作為課題負責人領導了JST和大阪府聯合主辦的“地域結集型共同研究事業-碳納米材料活用技術的創成”的研發項目和日本文部省“碳納米線圈的高效製備”研究課題。同時和三菱電機、日立造船、日本電子及大阪氣體等多家知名企業開展了共同研究。其研究成果多次被日本主要報刊所報導。