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反对现行主流微波吸收理论的一篇综述

已有 792 次阅读 2024-11-16 12:07 |个人分类:微波吸收|系统分类:科研笔记

1反对现行主流微波吸收理论的综述文章

标题:

Review of wave mechanics theory for microwave absorption by film

膜微波吸收研究在波动力学理论方向的新进展

https://fzkb.cbpt.cnki.net/WKB2/WebPublication/wkTextContent.aspx?colType=4&yt=2024&st=04

https://fzkb.cbpt.cnki.net/WKB2/WebPublication/paperDigest.aspx?paperID=d8c01f98-ec14-44a0-9da1-44b4b0bb6f22

https://fzkb.cbpt.cnki.net/WKB2/WebPublication/paperDigest.aspx?paperID=d8c01f98-ec14-44a0-9da1-44b4b0bb6f22

https://mall.cnki.net/eread/mall/forward/maga/FZKB202404.html

https://fzkb.cbpt.cnki.net/WKB2/WebPublication/kbDownload.aspx?fn=FZKB202404001

 

期刊:

JOURNAL OF MOLECULAR SCIENCE (分子科学学报)2024,4,300 -305

https://fzkb.cbpt.cnki.net/WKB2/WebPublication/wkTextContent.aspx?colType=4&yt=2024&st=04

 

[Article ID] 1000-9035(2024)04-300-06 DOI: 10.13563/j.cnki.jmolsci.2023.06.018

DOI: 10.13563/j.cnki.jmolsci.2023.06.018

 

分子科学学报(英文), 2024年04期

膜微波吸收研究在波动力学理论方向的新进展(英文)

刘跃;刘颖;DREW Michael G B;2024年04期 v.40;No.198 300-305页 [查看摘要][在线阅读][下载 1056K] 

期刊是不同观点争鸣的平台。

期刊发表一篇文章,并不表示期刊支持文章观点。

分子科学学报也发表支持微波吸收主流理论的文章:

 

分子科学学报(英文), 2024年02期

聚吡咯/钴钼氧化物的制备及微波吸收性能研究(英文)

王博;丛纪元;邢双喜;管洪涛;

采用表面原位生长法,将具有高磁导率的钴钼氧化物与聚吡咯复合,用以调节阻抗匹配,并探究复合材料的微波吸收性能。结果表示,所得聚吡咯/钴钼氧化物显示出优异的吸波性能,在匹配厚度为2.0 mm,频率为17.68 GHz处RL_(min)可达到-46.02 dB,有效吸收带宽达到4.08 GHz。聚吡咯/钴钼氧化物的吸波性能可归功于电导损耗、界面极化、偶极极化和涡流损耗等多种损耗机制的共同作用。

2024年02期 v.40;No.196 131-137页 [查看摘要][在线阅读][下载 2029K]

 

赞赏分子科学学报包容不同学术观点的态度。

 

2 文章发表期刊简介

分子科学学报现在是国内的英文刊物,是被Scopus数据库收录的国内核心期刊。

期刊简介

《分子科学学报》是由中国量子化学之父、中国科学院院士唐敖庆先生等老一辈科学家于1981年创办的化学专业期刊, 由中国科学技术协会主管、中国化学会和东北师范大学共同主办、东北师范大学化学学院编辑出版, 目前为双月刊。

《分子科学学报》以报道国内外分子科学领域的最新科研成果和学术动态为主要内容, 以繁荣我国科学技术事业, 促进国内外学术交流为宗旨,以促进学术交流和化学学科发展为己任,为广大科技工作者提供一个总结、交流、宣传科技成果的园地。

本刊主要刊发分子科学领域的学术论文和研究成果,读者对象主要为化学及相关专业研究生、教师和科研人员以及企业的研发人员,在国内外学术界享有一定声誉。

本刊为中文核心期刊、中国科技核心期刊、中国学术期刊综合评价数据库来源期刊、“《CAJ-CD 规范》执行优秀期刊”、吉林省第八次全省期刊等级评审“自然科学类十佳期刊”。并被中国核心期刊( 遴选) 数据库、中国学术期刊综合评价数据库、中文科技期刊数据库、中国学术期刊全文数据库、中国学术期刊文摘、中国生物学文摘、中国化学化工文摘、中国知网( CNKI) 、美国化学文摘( CA) 、俄罗斯文摘杂志(AJ) 等重要数据库收录。

 

分子科学学报(英文版) 创刊时间:1981 数据库收录情况: CA 化学文摘(美)(2020) Pж(AJ) 文摘杂志(俄)(2011) JST 日本科学技术振兴机构数据库(日)(2018) CSCD 中国科学引文数据库来源期刊(含扩展版): 2013-2014年度,2015-2016年度,2017-2018年度, 北京大学《中文核心期刊要目总览》来源期刊: 2008年版,2011年版,2014年版,2017年版本,2020年版 期刊荣誉: Caj-cd规范获奖期刊

 

《分子科学学报》被Scopus数据库收录

https://chem.nenu.edu.cn/info/1041/4592.htm

近日,经过Scopus数据库内容遴选与咨询委员会(Scopus Content Selection & Advisory Board,CSAB)的严格评审,我院编辑出版的《分子科学学报》被Scopus数据库正式收录。

Scopus是目前全球最大的文摘和引文数据库,由全球著名出版商爱思唯尔(EIsevier)研发,具有严格的评审标准,其收录的内容均由独立的、来自世界各地的CSAB专家采用透明标准严格审查,以确保内容品质和出版伦理。Scopus数据库由于其数据具有广泛性、准确性和代表性等特点,已受到国内外学术界普遍关注,目前世界大学排行榜、中国高被引学者榜单等都是采用Scopus数据库的数据做学科产出以及学科发展评估。

《分子科学学报》创刊于1981年,是由中国科协主管,中国化学会主办,我校化学学院编辑出版、国内外公开发行的化学类综合性学术期刊。该刊为北大版中文核心期刊、中国科技论文统计源期刊(中国科技核心期刊)、科技期刊世界影响力指数报告来源期刊(WJCI数据库),并被日本科学技术振兴机构数据库(JST数据库)、美国《化学文摘》(CA)等国际重要检索系统收录。

此次被Scopus数据库收录是《分子科学学报》发展中的又一项重要突破,标志着期刊的学术质量和出版质量得到了国际学术界和出版界的认可,这对进一步提升期刊的国际影响力、加强期刊建设具有重要意义。

 

3 文章主要内容

A 现行微波吸收理论混淆了膜和材料的不同

主要错误:

将从膜参数反射损失RL得到的结果错误的看成是材料的性质。实际上RL的结果只能用来表征膜的性质,因为它不是材料的性质。

纠正混淆膜和材料的错误为什么有意义:

因为错误的结果导致建立错误的阻抗匹配理论、错误的四分之一波长理论、错误的微波吸收机理等。

混淆膜和材料的错误不能被及时纠正的原因:

这些错误理论被认为是传输线理论的结果。

传输线理论是微波工程中的经典的电磁理论,是不会被推翻的完全正确的理论。

微波吸收的错误理论是对传输线理论的错误解释。

主要参考文献:

Yue Liu,Ying Liu,Michael G. B Drew,Wave Mechanics of Microwave Absorption in Films - Distinguishing Film from MaterialJournal of Magnetism and Magnetic Materials2024, 593, 171850

Ying Liu, Yi Ding, Yue Liu, Michael G. B. Drew. Unexpected Results in Microwave Absorption – Part 1: Different absorption mechanisms for metal-backed film and for materialSurfaces and Interfaces2023, 40, 103022

Ying Liu, Xiangbin Yin, Michael G. B. Drew, Yue Liu, Reflection Loss is a Parameter for Film, not MaterialNon-Metallic Material Science2023, 5(1): 38-48.

Ying Liu, Michael. G.B. Drew, Yue LiuChapter 4: Fundamental Theory of Microwave Absorption for Films of Porous Nanocomposites: Role of Interfaces in Composite-Fillers, in Porous Nanocomposites for Electromagnetic Interference Shielding, Edited by: Sabu Thomas, Claudio Paoloni, Avinash R. Pai2024Elsevier, [978-0-323-90035-5_B978-0-323-90035-5.00013-1], pp. 59 - 90, https://doi.org/10.1016/B978-0-323-90035-5.00013-1

 

B 现行微波吸收理论混淆了膜和材料吸收机理的不同

原因:

在固定频率下,材料的厚度越大,微波被吸收的越多;现行主流理论错误地认为以RL/dB表征的膜微波吸收峰是材料的共振吸收峰。

但是对于膜,膜的厚度越大,微波可以被吸收的更少。

微波吸收的波动力学理论认为:膜的微波吸收是波叠加的结果,而不是材料的固有性质。

实验结果在固定频率下,随着膜厚的的增加,微波吸收出现多个吸收峰。

这样的实验结果显然支持微波吸收的波动力学理论,否定现行微波吸收的主流理论。

主要参考文献:

Yue Liu,Ying Liu,Michael G. B Drew. ReviewWave mechanics of microwave absorption in films: a short reviewOptics and Laser Technology2024,178, 111211

Liu Y, Zhao K, Drew MGB, Liu Y. A theoretical and practical clarification on the calculation of reflection loss for microwave absorbing materialsAIP Advances 2018 , 8(1) 015223.

刘颖, 刘跃膜的微波吸收机理, 分子科学学报, 2023,v.39; No.194, 521-527

刘颖,丁一,陈庆阳,刘跃,NiFe2-xMxO4 (M: Ce/Sm/Gd)的制备及其膜的微波吸收性能沈阳师范大学学报 ( 自然科学版 )2023, 41(2),98 - 103

C 现行主流微波吸收理论中的阻抗匹配理论存在严重逻辑错误

现行微波吸收的阻抗匹配理论是混淆膜的输入阻抗和材料的特征阻抗的区别、错误地解释传输线理论结果。

现行微波吸收的阻抗匹配理论认为进入膜的微波越多,膜的微波吸收才能越大。

听上去,进入膜的微波越多,膜的微波吸收才能越大,似乎是常识。

但是

这个认知是错误的,是混淆了膜和材料的必然结果。

实验结果是:微波并不需要全部进入膜就能被膜全部吸收,

这个实验结果(似乎违背常识)广为实验文章报道,但是只有在微波吸收的波动力学理论提出后才被揭示出来、被认知的。以前没有注意到实验数据中包含这个结果。

主要参考文献:

Ying Liu, Michael G. B. Drew, Yue Liu, A physics investigation on impedance matching theory in microwave absorption film—Part 2: Problem AnalysesJournal of Applied Physics2023, 134(4), 045304

Yue Liu, Michael G. B Drew,Ying Liu, A Theoretical Exploration of Impedance Matching Coefficients for Interfaces and FilmsApplied Physics A2024, 130, 212

D 现行主流微波吸收理论中的四分之一波长理论是错误的

膜是由材料和前后两个平行界面组成的器件。

四分之一波长理论中的存在的问题:

现行主流微波吸收理论中的四分之一波长理论是忽略了界面的相位效应而得到的错误理论。

膜的界面的相位效应很大,是不能忽略的。

一个主要错误是混淆了膜的两个平行界面和材料颗粒之间的界面的不同。

主要参考文献:

Liu YLiu Y, Drew MGB. A theoretical investigation of the quarter-wavelength model  part 2: verification and extensionPhysica Scripta 2022 , 97(1) 015806.

Ying Liu, Yue Liu, Drew M.G.B, A re-evaluation of the mechanism of microwave absorption in film  Part 3: Inverse relationshipMater. Chem. Phys2022, 290, 126521

Yue Liu,Ying Liu,Michael G. B Drew,Wave Mechanics of Microwave Absorption in Films: Multilayered FilmsJournal of Electronic Materials2024, doi: 10.1007/s11664-024-11370-9

E 微波吸收的波动力学理论解决了原来不可能解决的问题

根据现行主流微波吸收理论,应该在膜厚度等于1/4波长处出现的吸收峰都无例外地偏离1/4波长。文献中有多篇现行主流微波吸收理论文章试图解释这个问题,但是没有一个能解决这个问题。所有的解决方案都非常复杂难懂,而且被证明是错误的,因为错误的现行主流微波吸收理论根本没有能力解决这个问题。

参考文献:

Ying Liu, Yue Liu, Drew M.G.B, A re-evaluation of the mechanism of microwave absorption in film  Part 3: Inverse relationshipMater. Chem. Phys2022, 290, 126521.

Ying Liu, Michael G. B. Drew, Yue Liu, A physics investigation on impedance matching theory in microwave absorption film—Part 2: Problem AnalysesJournal of Applied Physics2023, 134(4), 045304

 

Yue Liu, Ying Liu, Michael G. B. Drew,  Review:  Recognizing Problems in Publications Concerned with Microwave Absorption Film and Providing Corrections: A Focused ReviewQeios, preprin,  2024-07-01, Supplementary data,   Yue Liu, Ying Liu, Drew MGB,  [Commentary] Comments on: “A perspective on impedance matching and resonance absorption mechanism for electromagnetic wave absorbing” by Hou et al. [Carbon 222 (2024) 118935]Qeios2024Supplementary Yue Liu, Ying Liu, Drew MGB, Corrections of common errors in current theories of microwave absorption caused by confusing film and materialQeios2024/02/10, preprint, https://doi.org/10.32388/QQ1MFF;  Corrections of Common Errors Associated with the Confusion between Film and Material in Current Theories of Microwave Absorption. Available at SSRN: https://ssrn.com/abstract=4797207 or http://dx.doi.org/10.2139/ssrn.4797207 

在新创立的微波吸收的波动力学理论中,该问题被更准确地表述为:

微波吸收峰总是出现在膜的前界面的反射光束r1和膜的后界面的反射光束r2的相位差不是正好是180度。

这个小偏移能用微波吸收的波动力学理论非常简单地概括出来。

 

F 微波吸收的波动力学建立的新概念是革命性的概念

仅仅因为将波粒二象性引入经典波动方程的小灵感就建立了宏大的量子力学学科,伴随产生大量革命性的概念。

波粒二象性和经典波动方程都是被实验验证过的理论, 两者的结合是量子力学的基本假定。

将波粒二象性引入经典波动方程的小灵感之后的工作就是数学了。

最本质的量子力学的基本假定实际只有一条

建立微波吸收的波动力学理论的灵感仅仅是因为发现现代主流微波吸收理论混淆了膜和材料的区别。

我们抓住这个小小的灵感,在大学本科波叠加原理的基础上,用简单的形而上学的数学建立了整个微波吸收的波动力学理论体系,

微波吸收的波动力学理论与量子力学一样,都借助于波动力学理解世界,建立了一系列革命性的概念。

说明看似平凡的经典波动力学真是伟大的科学理论。

所谓革命性的概念,就是原来的错误理论和概念看上去似乎符合常识,新建立的革命性概念则似乎违背常识。

G 在现行微波吸收主流理论的文章中,物理低级错误经常发生而从来没有被纠正

参考文献:

 Yue Liu, Ying Liu, Michael G. B. Drew,  Review:  Recognizing Problems in Publications Concerned with Microwave Absorption Film and Providing Corrections: A Focused ReviewQeios, preprin,  2024-07-01, Supplementary data,   Yue Liu, Ying Liu, Drew MGB,  [Commentary] Comments on: “A perspective on impedance matching and resonance absorption mechanism for electromagnetic wave absorbing” by Hou et al. [Carbon 222 (2024) 118935]Qeios2024Supplementary Yue Liu, Ying Liu, Drew MGB, Corrections of common errors in current theories of microwave absorption caused by confusing film and materialQeios2024/02/10, preprint, https://doi.org/10.32388/QQ1MFF;  Corrections of Common Errors Associated with the Confusion between Film and Material in Current Theories of Microwave Absorption. Available at SSRN: https://ssrn.com/abstract=4797207 or http://dx.doi.org/10.2139/ssrn.4797207 

 

4 面临的问题

尽管正确的微波吸收的波动力学理论已经建立,错误的现行微波吸收的主流理论仍然主宰主流媒体。大量应用错误理论的文章仍然大量发表,根本不提反对理论。正确的理论文章仍然很难发表。

原因:

4.1真正搞懂微波吸收的波动力学理论,仅仅学过波叠加原理是不够的,必须真正理解波叠加原理

没有真正理解波叠加原理典型的标志性错误是混淆独立界面和膜中的界面的不同。波叠加中分光束的不能定义能量,但是学界普遍用分光束的振幅定义分光束的能量。

Ying Liu, Michael G. B. Drew, Yue Liu, A physics investigation on impedance matching theory in microwave absorption film—Part 2: Problem AnalysesJournal of Applied Physics2023, 134(4), 045304

4.2 数值验算

将已经发表的实验数据带入膜的前后两个界面的反射系数RMR2的理论公式,很容易验证是微波吸收的波动力学理论是正确的,还是现行微波吸收的主流理论是正确的。

RMR2的理论公式与反射损失RL计算公式的数学验算难度相同,

但是用RL验算有现成的商业软件,

RMR2的理论公式的验算需要自己编程,这也许是阻碍人们判断哪个理论正确的障碍。

现代科学研究者的理论水平极低

 

4.3 错误理论仅仅是对实验结果的一种理论解释,而正确的理论是对实验结果的正确认知

微波吸收的波动力学的新理论是建立在形而上学方法的基础上,没有歧义、是切中要害的简单理论。

现行微波吸收的主流理论对于理论和实验结果之间的矛盾只能用辩证的方法解释。

不能把正确的理论仅仅看成是对实验结果的解释,

正确的理论是对实验结果的理论认知:

正确的理论揭示实验结果背后的本质、确切而没有歧义的认知实验结果,真正透彻的理解实验结果,指导进一步的实验设计。

错误理论仅仅是对实验结果的一种理论解释不是对实验结果的认知

错误理论对实验结果的解释牵强附会不得要领,对实验设计没有指导意义。

5 已经发表的微波吸收波动力学理论的文章

文献1 – 22 主要讨论膜,文献23 -29 主要讨论材料。

  1. Yue Liu,      Ying Liu, Michael G. B. Drew, Review: 膜微波吸收研究在波动力学理论方向的新进展, 分子科学学报(英文版, Journal of Molecular Science), 2024, 4, 300      -305; Review of Wave Mechanics Theory for Microwave      Absorption by FilmQeios, Preprint, 2024-07-04, Supplementary data

  2.   Yue      Liu, Ying Liu, Michael G. B. Drew,  Review:  Recognizing Problems in Publications      Concerned with Microwave Absorption Film and Providing Corrections: A      Focused ReviewQeios, preprin,  2024-07-01, Supplementary data,   Yue Liu, Ying Liu,      Drew MGB,  [Commentary] Comments on: “A      perspective on impedance matching and resonance absorption mechanism for      electromagnetic wave absorbing” by Hou et al.      [Carbon 222 (2024) 118935]Qeios2024Supplementary Yue Liu, Ying Liu,      Drew MGB, Corrections of common errors in current theories of      microwave absorption caused by confusing film and materialQeios2024/02/10,      preprint, https://doi.org/10.32388/QQ1MFF;  Corrections of Common Errors Associated with the      Confusion between Film and Material in Current Theories of Microwave      Absorption. Available at SSRN: https://ssrn.com/abstract=4797207 or      http://dx.doi.org/10.2139/ssrn.4797207 

  3.  Yue Liu,Ying Liu,Michael G. B Drew. ReviewWave mechanics of microwave absorption      in films: a short reviewOptics and Laser Technology2024,      178,  111211  (The      wave mechanics for microwave absorption film-Part 1: A short review, Preprint, Research Square, 15 Aug, 2023, scite

  4. Yue Liu,Ying Liu,Michael G. B Drew,Wave Mechanics of Microwave Absorption in Films -      Distinguishing Film from MaterialJournal of Magnetism and Magnetic Materials2024, 593, 171850 ;          ( The wave mechanics for microwave      absorption film – Part 2: The difference between film and material,Preprint, Research Square, 15 Aug, 2023, Supplementarial      file)

  5. Yue Liu,Ying Liu,Michael G. B Drew,Wave Mechanics of Microwave Absorption      in Films: Multilayered FilmsJournal of Electronic Materials2024,      doi: 10.1007/s11664-024-11370-9; The wave mechanics for microwave absorption      film-Part 3: Film with multilayers, Preprint, Research Square, 13 Aug, 2023,Supplementarial      filescite_

  6.   Yue Liu, Michael G. B Drew,Ying Liu, A Theoretical Exploration of Impedance      Matching Coefficients for Interfaces and FilmsApplied Physics A2024,      130, 212

  7. Ying Liu,      Michael. G.B. Drew, Yue LiuChapter 4: Fundamental Theory of Microwave      Absorption for Films of Porous Nanocomposites: Role of Interfaces in      Composite-Fillers, in Porous      Nanocomposites for Electromagnetic Interference Shielding, Edited by: Sabu Thomas, Claudio Paoloni, Avinash      R. Pai2024Elsevier,      [978-0-323-90035-5_B978-0-323-90035-5.00013-1], pp. 59 -      90, https://doi.org/10.1016/B978-0-323-90035-5.00013-1

  8. 刘颖, 刘跃膜的微波吸收机理, 分子科学学报, 2023,v.39; No.194(06) 521-527

  9. Ying Liu,      Kaiqi Yang, Yue Liu, Michael G. B Drew, The Shackles of      Peer Review: Unveiling the Flaws in the Ivory TowerarXiv,      https://doi.org/10.48550/arXiv.2310.05966

  10. Ying Liu,      Michael G. B. Drew, Yue Liu, A physics      investigation on impedance matching theory in microwave absorption film—Part 1: Theory, Journal      of Applied Physics2023, 134(4), 045303, DOI:      10.1063/5.0153608

  11. Ying Liu,      Michael G. B. Drew, Yue Liu, A physics      investigation on impedance matching theory in microwave absorption film—Part      2: Problem AnalysesJournal of Applied Physics2023,      134(4), 045304, DOI: 10.1063/5.0153612

  12. Ying      Liu; Xiangbin Yin; M. G. B. Drew; Yue Liu, Microwave absorption of film explained      accurately by wave cancellation theoryPhysica B: Condensed Matter2023,      666, 415108. (Microwave      absorption of film explained accurately by wave cancellation theory2023-02-23 | Preprint, Research Square, DOI: 10.21203/rs.3.rs-2616469/v2Supplementary      information: Available comments and our responses.)

  13. Ying Liu,      Yi Ding, Yue Liu, Michael G. B. Drew. Unexpected Results in Microwave      Absorption – Part 1: Different absorption mechanisms for      metal-backed film and for materialSurfaces and      Interfaces2023, 40, 103022

  14. Ying Liu,      Yi Ding, Yue Liu, Michael G. B. Drew. Unexpected Results in Microwave      Absorption – Part 2:. Angular effects and the wave cancellation      theorySurfaces and Interfaces, 2023, 40, 103024

  15. Ying Liu,      Xiangbin Yin, Michael G. B. Drew, Yue Liu, Reflection Loss      is a Parameter for Film, not MaterialNon-Metallic Material Science2023,      5(1): 38-48.

  16. 刘颖,丁一,陈庆阳,刘跃,NiFe2-xMxO4 (M:      Ce/Sm/Gd)的制备及其膜的微波吸收性能沈阳师范大学学报 ( 自然科学版 )2023, 41(2),98 - 103

  17. Ying Liu,      Yue Liu, Drew M.G.B, A re-evaluation of the mechanism of      microwave absorption in film – Part 1: Energy conservationMater. Chem. Phys2022,      290,126576.

  18. Ying Liu,      Yue Liu, Drew M.G.B, A re-evaluation of the mechanism of      microwave absorption in film – Part 2: The Real mechanismMater. Chem. Phys,. 2022,      291, 126601.

  19. Ying Liu,      Yue Liu, Drew M.G.B, A re-evaluation of the mechanism of      microwave absorption in film  Part 3: Inverse relationshipMater. Chem. Phys2022,      290, 126521.

  20. Liu YLiu Y, Drew MGB. A theoretical investigation of the      quarter-wavelength model  part 2: verification and extensionPhysica Scripta      2022 , 97(1) 015806.

  21. Liu Y, Liu Y, Drew MGB. A theoretical      investigation on the quarter-wavelength model — part 1: analysisPhysica Scripta      2021 , 96(12) 125003. ( The problems in the quarter-wavelength      model and impedance matching theory in analysising microwave absorption      material, 2021-08-30 | Preprint, Research Square, DOI: 10.21203/rs.3.rs-206241/v1)

  22. Liu Y, Drew MGB, Li H, Liu Y. A theoretical analysis of the      relationships shown from the general experimental results of scattering      parameters s11 and s21 – exemplified by the film of      BaFe12-iCeiO19/polypyrene with i = 0.2,      0.4, 0.6Journal of Microwave Power and Electromagnetic Energy      2021 , 55(3) 197-218.

  23. Liu Y, Drew MGB, Li H, Liu YAn experimental and theoretical      investigation into methods concerned with “reflection loss”      for microwave absorbing materialsMaterials      Chemistry and Physics 2020 , 243 122624.

  24. Liu Y, Lin Y, Zhao K, Drew MGB, Liu YMicrowave absorption properties of      Ag/NiFe2-xCexO4 characterized by an alternative procedure rather than the      main stream method using “reflection lossMaterials      Chemistry and Physics 2020 , 243 122615

  25. 赵坤 , 林雨冉 , 刘颖 . 微波吸收复合材料      Ag/NiFe2-xCexO4 的制备与表征功能材料 2020 , 51(03) 03171      - 03175.

  26. Liu Y, Drew MGB, Liu Y. Characterization microwave absorption      from active carbon/BaSmxFe12−xO19/polypyrrole composites      analyzed with a more rigorous method. Journal of      Materials Science: Materials in Electronics 2019, 30(2) 1936-1956.

  27. Yang K,      Liu Y, Drew MGB, Liu Y. Preparation and characterization of      BaSmxFe12 −      xO19/polypyrrole composites. Journal of Materials Science:      Materials in Electronics 2018 , 29(15) 13148-13160Electronic      supplementary material.

  28. Liu Y,      Zhao K, Drew MGB, Liu Y. A theoretical and      practical clarification on the calculation of reflection loss for      microwave absorbing materialsAIP Advances 2018 , 8(1) 015223.

  29. Liu Y, Yu      H, Drew MGB, Liu Y. A systemized parameter set applicable      to microwave absorption for ferrite based materialsJournal of      Materials Science: Materials in Electronics 2018, 29(2) 1562-1575,Supplementary      material.

  30. Liu Y, Tai      R, Drew MGB, Liu Y. Several Theoretical Perspectives of      Ferrite-Based Materials—Part 1: Transmission Line Theory      and Microwave AbsorptionJournal of Superconductivity and Novel      Magnetism 2017 , 30(9) 2489-2504.

其它课题组的相关文章:

https://onlinelibrary.wiley.com/doi/10.1002/smll.202305277

https://doi.org/10.1002/smll.202305277

The Developed Wave Cancellation Theory Contributing to Understand Wave Absorption Mechanism of ZIF Derivatives with Controllable Electromagnetic Parameters

 

https://onlinelibrary.wiley.com/doi/10.1002/pssa.202300828

https://doi.org/10.1002/pssa.202300828

Theory, Modeling, Measurement, and Testing of Electromagnetic Absorbers: A Review

 

6 课题组的全部论文

对于任何领域的科学研究,研究者的知识视野不能仅仅局限于单一的一个领域

特点:

Journal of Chemical Education是化学教育的顶刊,American Journal of Physics是物理教育的顶刊。这两个刊物,国内作者的文章都不多。前者我们发表4篇文章(文章62 – 65),后者我们发表1篇文章(文章33)。

我们的工作都是基础研究,或者可以说是教学内容研究。但是我们把教学内容研究的文章发到了研究性期刊,如微波吸收的波动力学理论。其它主要文章包括文章1 – 3, 文章 26等

我们在数学刊物Journal of Mathematical Chemistry发表论文6篇(文章49 - 54)。

我们主要的文发表在物理刊物上、以及化学、材料刊物上。

我们在晶体结构方面也有所建树(文章2,3,45,46,56等)。

大多数文章的主题是纠错。

1.     Yue Liu, Ying Liu, Drew MGB. ReviewThe handedness structure of octahedral metal complexes with chelating ligandsCoordination Chemistry Reviews 2014 , 260 37-64.

2.     Ying Liu, Yue Liu, Drew MGB. Review:   Comparison of calculations for interplanar distances in a crystal latticeCrystallography Reviews 2017 , 23(4) 252-301.

3.     Ying LiuYue Liu, Drew MGB. Review: Clarifications of concepts concerning interplanar spacing in crystals with reference to recent publicationsSN Applied Sciences 2020 , 2(4) 755.

4.      Yue Liu, Ying Liu, Michael G. B. Drew, Review: 膜微波吸收研究在波动力学理论方向的新进展, 分子科学学报(英文版, Journal of Molecular Science), 2024, 4, 300 -305; Review of Wave Mechanics Theory for Microwave Absorption by FilmQeios, Preprint, 2024-07-04, Supplementary data

5.       Yue Liu, Ying Liu, Michael G. B. Drew,  Review:  Recognizing Problems in Publications Concerned with Microwave Absorption Film and Providing Corrections: A Focused ReviewQeios, preprin,  2024-07-01, Supplementary data,   Yue Liu, Ying Liu, Drew MGB,  [Commentary] Comments on: “A perspective on impedance matching and resonance absorption mechanism for electromagnetic wave absorbing” by Hou et al. [Carbon 222 (2024) 118935]Qeios2024Supplementary Yue Liu, Ying Liu, Drew MGB, Corrections of common errors in current theories of microwave absorption caused by confusing film and materialQeios2024/02/10, preprint, https://doi.org/10.32388/QQ1MFF;  Corrections of Common Errors Associated with the Confusion between Film and Material in Current Theories of Microwave Absorption. Available at SSRN: https://ssrn.com/abstract=4797207 or http://dx.doi.org/10.2139/ssrn.4797207 

6.      Yue Liu,Ying Liu,Michael G. B Drew. ReviewWave mechanics of microwave absorption in films: a short reviewOptics and Laser Technology2024, 178,  111211  (The wave mechanics for microwave absorption film-Part 1: A short review, Preprint, Research Square, 15 Aug, 2023, scite

7.     Yue Liu,Ying Liu,Michael G. B Drew,Wave Mechanics of Microwave Absorption in Films - Distinguishing Film from MaterialJournal of Magnetism and Magnetic Materials2024, 593, 171850 ;     ( The wave mechanics for microwave absorption film – Part 2: The difference between film and material,Preprint, Research Square, 15 Aug, 2023, Supplementarial file)

8.     Yue Liu,Ying Liu,Michael G. B Drew,Wave Mechanics of Microwave Absorption in Films: Multilayered FilmsJournal of Electronic Materials2024, doi: 10.1007/s11664-024-11370-9; The wave mechanics for microwave absorption film-Part 3: Film with multilayers, Preprint, Research Square, 13 Aug, 2023,Supplementarial filescite_

9.       Yue Liu, Michael G. B Drew,Ying Liu, A Theoretical Exploration of Impedance Matching Coefficients for Interfaces and FilmsApplied Physics A2024, 130, 212

10.   Ying Liu, Michael. G.B. Drew, Yue LiuChapter 4: Fundamental Theory of Microwave Absorption for Films of Porous Nanocomposites: Role of Interfaces in Composite-Fillers, in Porous Nanocomposites for Electromagnetic Interference Shielding, Edited by: Sabu Thomas, Claudio Paoloni, Avinash R. Pai2024Elsevier, [978-0-323-90035-5_B978-0-323-90035-5.00013-1], pp. 59 - 90, https://doi.org/10.1016/B978-0-323-90035-5.00013-1

11.   刘颖, 刘跃膜的微波吸收机理, 分子科学学报, 2023,v.39; No.194(06) 521-527

12.   Ying Liu, Kaiqi Yang, Yue Liu, Michael G. B Drew, The Shackles of Peer Review: Unveiling the Flaws in the Ivory TowerarXiv, https://doi.org/10.48550/arXiv.2310.05966

13.   Ying Liu, Review of: The Compton Wavelength Is the True Matter Wavelength, Linked to the Photon Wavelength, While the de Broglie Wavelength Is Simply a Mathematical DerivativeQeios, 2023, https://doi.org/10.32388/YLQG7T

14.   Ying Liu, Review of: Some Considerations on the Speed of Light. https://doi.org/10.32388/34DN8G

15.   Ying Liu, Michael G. B. Drew, Yue Liu, A physics investigation on impedance matching theory in microwave absorption film—Part 1: Theory, Journal of Applied Physics2023, 134(4), 045303, DOI: 10.1063/5.0153608

16.   Ying Liu, Michael G. B. Drew, Yue Liu, A physics investigation on impedance matching theory in microwave absorption film—Part 2: Problem AnalysesJournal of Applied Physics2023, 134(4), 045304, DOI: 10.1063/5.0153612

17.   Ying Liu; Xiangbin Yin; M. G. B. Drew; Yue Liu, Microwave absorption of film explained accurately by wave cancellation theoryPhysica B: Condensed Matter2023, 666, 415108. (Microwave absorption of film explained accurately by wave cancellation theory2023-02-23 | Preprint, Research Square, DOI: 10.21203/rs.3.rs-2616469/v2Supplementary information: Available comments and our responses.)

18.   Ying Liu, Yi Ding, Yue Liu, Michael G. B. Drew. Unexpected Results in Microwave Absorption – Part 1: Different absorption mechanisms for metal-backed film and for materialSurfaces and Interfaces2023, 40, 103022

19.   Ying Liu, Yi Ding, Yue Liu, Michael G. B. Drew. Unexpected Results in Microwave Absorption – Part 2:. Angular effects and the wave cancellation theorySurfaces and Interfaces, 2023, 40, 103024

20.   Ying Liu, Xiangbin Yin, Michael G. B. Drew, Yue Liu, Reflection Loss is a Parameter for Film, not MaterialNon-Metallic Material Science2023, 5(1): 38-48.

21.   刘颖,丁一,陈庆阳,刘跃,NiFe2-xMxO4 (M: Ce/Sm/Gd)的制备及其膜的微波吸收性能沈阳师范大学学报 ( 自然科学版 )2023, 41(2),98 - 103

22.   尹相镔, 郝艺彤, 王瑞丹, 刘颖, 戚克振. 铈掺杂ZnFe2O4 多层空心微球的制备及其光催化活性. 硅酸盐学报202351(1), 58 - 63.

23.   Ying Liu, Yue Liu, Drew M.G.B, A re-evaluation of the mechanism of microwave absorption in film – Part 1: Energy conservationMater. Chem. Phys2022, 290,126576.

24.   Ying Liu, Yue Liu, Drew M.G.B, A re-evaluation of the mechanism of microwave absorption in film – Part 2: The Real mechanismMater. Chem. Phys,. 2022, 291, 126601.

25.   Ying Liu, Yue Liu, Drew M.G.B, A re-evaluation of the mechanism of microwave absorption in film  Part 3: Inverse relationshipMater. Chem. Phys2022, 290, 126521.

26.   Liu Ying, Liu Yue, Drew Michael G. B. Natural mathematical derivation of the Gibbs-Duhem Equation related to ΔG and ∂G/∂ξ, International Journal of Thermophysics, 2022, 43, 73 doi: 10.1007/s10765-022-02998-y. ( Natural Mathematical Derivation of the Gibbs-Duhem Equation, 2022-03-10 | Preprint, Research Square, DOI: 10.21203/rs.3.rs-1061987/v1)

27.   Song J, Zhao K, Yin X, Liu Y, Khan I and Liu S-Y. Photocatalytic degradation of tetracycline hydrochloride with g-C3N4/Ag/AgBr compositesFront. Chem. 2022, 10:1069816. doi: 10.3389/fchem.2022.1069816

28.   刘颖, 郝艺彤, 尹相镔, 崔楠, 戚克振. Ag@ZnFe2-xCeO4复合材料的制备及其光催化活性沈阳师范大学学报 ( 自然科学版 )2022, 40(1), 1 - 5.

29.   Liu YLiu Y, Drew MGB. A theoretical investigation of the quarter-wavelength model  part 2: verification and extensionPhysica Scripta 2022 , 97(1) 015806.

30.   Liu Y, Liu Y, Drew MGB. A theoretical investigation on the quarter-wavelength model — part 1: analysisPhysica Scripta 2021 , 96(12) 125003. ( The problems in the quarter-wavelength model and impedance matching theory in analysising microwave absorption material, 2021-08-30 | Preprint, Research Square, DOI: 10.21203/rs.3.rs-206241/v1)

31.   Liu Y, Drew MGB, Li H, Liu Y. A theoretical analysis of the relationships shown from the general experimental results of scattering parameters s11 and s21 – exemplified by the film of BaFe12-iCeiO19/polypyrene with i = 0.2, 0.4, 0.6Journal of Microwave Power and Electromagnetic Energy 2021 , 55(3) 197-218.

32.   刘颖, 林雨冉, 覃佩 , 申婉婷, 赵坤. 二氧化铈 - 银 _ 碘化银光催化剂的制备及水中有机污染物去除性能 . 沈阳师范大学学报 ( 自然科学版 ) 2021 , 39(4) 290 - 296.

33.   Liu YLiu Y, Drew MGB. Relationship between heat capacities derived by different but connected approachesAmerican Journal of Physics 2020 , 88(1) 51-59.

34.   Liu Y, Drew MGB, Li H, Liu YAn experimental and theoretical investigation into methods concerned with “reflection loss” for microwave absorbing materialsMaterials Chemistry and Physics 2020 , 243 122624.

35.   Liu Y, Lin Y, Zhao K, Drew MGB, Liu YMicrowave absorption properties of Ag/NiFe2-xCexO4 characterized by an alternative procedure rather than the main stream method using “reflection lossMaterials Chemistry and Physics 2020 , 243 122615

36.   Zhao K, Khan I, Qi K, Liu Y, Khataee A. Ionic liquid assisted preparation of phosphorus-doped g-C3N4 photocatalyst for decomposition of emerging water pollutantsMaterials Chemistry and Physics 2020 , 253 123322.

37.   Zhang S, Khan I, Qin X, Qi K, Liu Y, Bai S. Construction of 1D Ag-AgBr/AlOOH Plasmonic Photocatalyst for Degradation of Tetracycline HydrochlorideFront Chem 2020 , 8 117.

38.   赵坤 , 林雨冉 , 刘颖 . 微波吸收复合材料 Ag/NiFe2-xCexO4 的制备与表征功能材料 2020 , 51(03) 03171 - 03175.

39.   Liu Y, Drew MGB, Liu Y. Characterization microwave absorption from active carbon/BaSmxFe12−xO19/polypyrrole composites analyzed with a more rigorous method. Journal of Materials Science: Materials in Electronics 2019, 30(2) 1936-1956.

40.   Yang K, Liu Y, Drew MGB, Liu Y. Preparation and characterization of BaSmxFe12 − xO19/polypyrrole composites. Journal of Materials Science: Materials in Electronics 2018 , 29(15) 13148-13160Electronic supplementary material.

41.   Liu Y, Zhao K, Drew MGB, Liu Y. A theoretical and practical clarification on the calculation of reflection loss for microwave absorbing materialsAIP Advances 2018 , 8(1) 015223.

42.   Liu Y, Drew MGB, Liu Y. Similarity Between Chemistry and Mathematics in ReasoningThe Chemical Educator 2018 , 23 231-236.

43.   Liu Y, Yu H, Drew MGB, Liu Y. A systemized parameter set applicable to microwave absorption for ferrite based materialsJournal of Materials Science: Materials in Electronics 2018, 29(2) 1562-1575,Supplementary material.

44.   Liu Y, Tai R, Drew MGB, Liu Y. Several Theoretical Perspectives of Ferrite-Based Materials—Part 1: Transmission Line Theory and Microwave AbsorptionJournal of Superconductivity and Novel Magnetism 2017 , 30(9) 2489-2504.

45.   Liu Y, Jin J, B. Drew MG, Liu Y. Several Theoretical Perspectives of Ferrite-Based Materials—Part 2: Close Packing Model for Crystal StructureJournal of Superconductivity and Novel Magnetism 2017 , 30(10) 2777-2789.

46.   Liu Y, Liu Y, Yin H, Drew MGB. Several Theoretical Perspectives of Ferrite-Based Materials-Part 3: Crystal Structure and SynthesisJournal of Superconductivity and Novel Magnetism 2017 , 30(11) 3019-3025.

47.   Liu Y, Tai R, Drew MGB, Liu Y. Preparation and characterizations of active carbon/barium ferrite/polypyrrole compositesJournal of Materials Science: Materials in Electronics 2017 , 28(9) 6448-6455.

48.   Jin J, Liu Y, Drew MGB, Liu Y. Preparation and characterizations of Ba1 − xPbxFe12O19/polypyrrole composites. Journal of Materials Science: Materials in Electronics 2017 , 28(15) 11325-11331.

49.   Liu Y, Liu Y, Drew MGB. A mathematical approach to chemical equilibrium theory for gaseous systems—I: theoryJournal of Mathematical Chemistry 2012 , 51(2) 715-740.

50.   Liu Y, Liu Y, Drew MGB. A mathematical approach to chemical equilibrium theory for gaseous systems—II: extensions and applicationsJournal of Mathematical Chemistry 2012 , 51(2) 741-762.

51.   Liu Y, Drew MGB, Liu Y. A mathematical approach to chemical equilibrium theory for gaseous systems—III: Qp,Qc,and QxJournal of Mathematical Chemistry 2014 , 52(5) 1191-1200.

52.   Liu Y, Liu Y, Drew MGB. A mathematical approach to chemical equilibrium theory for gaseous systems IV: a mathematical clarification of Le Chatelier's principleJournal of Mathematical Chemistry 2015 , 53(8) 1835-1870.

53.   Liu Y, Liu Y, Drew MGB. Correlation between Fourier series expansion and Hückel orbital theoryJournal of Mathematical Chemistry 2012 , 51(2) 503-531.

54.   Liu Y, Liu B, Liu Y, Drew MGB. Correlations between two sets of angular relation equationsJournal of Mathematical Chemistry 2011 , 49(9) 2089-2108.

55.   Liu Y, Li X, Drew MGB, Liu Y. Increasing microwave absorption efficiency in ferrite based materials by doping with lead and forming compositesMaterials Chemistry and Physics 2015 , 162 677-685.

56.   刘颖 , 台睿 , 刘跃 . 晶体场与磁学性质 . 化学教育 (Chinese Journal of Chemical Education), 2015 , 36(6) 1-10.

57.   Liu Y, Drew MGB, Liu Y, Liu Y, Cao FL. A comparative study of Fe3O4/polyaniline composites with octahedral and microspherical inorganic kernelsJournal of Materials Science 2014 , 49(10) 3694-3704.

58.   刘跃. 坚持基础研究,做有科学意义的工作 . 化学通讯 2014 (1) 14.

59.   刘跃, 李晓杰 , 刘颖 . 也谈平衡移动 . 化学教与学 2013 , 7 70-72.

60.   刘颖, 刘跃. 立方 ZnS 晶胞中 Zn-S 键长的几种解法及其启示化学教学 2013 (1) 70 - 72.

61.   Liu Y, Liu Y, Drew MGB. The use of Three Simple Related Procedures in Determining the Russell-Saunders Terms of Equivalent ElectronsThe Chemical Educator 2012 , 17 118-124.

62.   Liu Y, Drew MGB, Liu Y, Liu L. Anodic Polarization Curves RevisitedJournal of Chemical Education 2012 , 90(1) 76-81

63.   Liu Y, Liu B, Liu Y, Drew MGB. Connections between Concepts Revealed by the Electronic Structure of Carbon MonoxideJournal of Chemical Education 2011 , 89(3) 355-359.

64.   Liu Y, Liu Y, Liu B. A New Method for Obtaining Russell − Saunders Terms. Journal of Chemical Education 2010 , 88(3) 295-298.

65.   Liu Y, Liu Y, Drew MGB. Where Should the Nuclei Be LocatedJournal of Chemical Education 2005 , 82(2) 320 - 322.

66.   Liu Y, Drew MGB, Liu Y. Optimizing the methods of synthesis for barium hexagonal ferrite—An experimental and theoretical studyMaterials Chemistry and Physics 2012 , 134(1) 266-272.

67.   Wang J, Wu C, Xia T, Liu Y, Feng J, Zhang M. Preparation, characterizations and magnetic properties of doped barium hexaferrites BaFe12-2x Mn x Sn x O19 (x = 0.0–1.0)Journal of Wuhan University of Technology-Mater Sci Ed 2012 , 27(3) 507-511.

68.   王丽丽, 李阳, 刘颖, 刘跃, 磷掺杂锐钛矿二氧化钛能带结构的从头计算研究分子科学学报 2012, 28(3)248 - 251, DOI: 10.13563/j.cnki.jmolsci.2012.03.013

69.   Liu Y, Zhang HB, Duan JD, Liu Y, Gao Y, Wang LL , et al. Magnetic Properties of Mn/Co/Sn Substituted Barium Hexaferrites Synthesized by an Improved Co-Precipitation MethodAdvanced Materials Research 2011 , 239-242 3052-3055.

70.   Liu Y, Yin HS, Liu Y, Sun K, Li Y, Wang LL , et al. Improved Synthesis Methods for Barium HexaferriteAdvanced Materials Research 2011 , 239-242 3039-3042.

71.   Liu Y, Liu Y, Drew MGB. Aspects of quantum mechanics clarified by lateral thinkingThe Chemical Educator 2011 , 16 272-274.

72.   Liu Y, Liu B, Liu Y, Drew MGB. Observations on calculations of configuration interaction and basis set superposition errorThe Chemical Educator, 2011: 202-205.

73.   Liu Y, Li Y, Liu Y, Yin HS, Wang LL, Sun K , et al. Structure Information of Barium Hexaferrite and Strategies for its SynthesesApplied Mechanics and Materials 2011 , 69 6-11.

74.   Liu Y, Drew MGB, Liu Y. Preparation and magnetic properties of barium ferrites substituted with manganese, cobalt, and tin. Journal of Magnetism and Magnetic Materials 2011 , 323(7) 945-953.

75.   刘颖, 段纪东, 张洪波, 刘跃. 烯烃催化聚合反应中的区位选择性和 Mulliken 位置电荷高分子通报 (CHINESE POLYMER BULLETIN) 2011 (5) 93-97.

76.   Liu Y, Drew MGB, Wang J, Zhang M, Liu Y. Efficiency and purity control in the preparation of pure and/or aluminum-doped barium ferrites by hydrothermal methods using ferrous ions as reactantsJournal of Magnetism and Magnetic Materials 2010 , 322(3) 366-374.

77.   Liu Y, Drew MGB, Liu Y, Wang J, Zhang M. Preparation and magnetic properties of La–Mn and La–Co doped barium hexaferrites prepared via an improved co-precipitation/molten salt methodJournal of Magnetism and Magnetic Materials 2010 , 322(21) 3342-3345.

78.   Liu Y, Drew MGB, Liu Y, Wang J, Zhang M. Preparation, characterization and magnetic properties of the doped barium hexaferrites BaFe12 − 2xCox/2Znx/2SnxO19, x=0.0 – 2.0. Journal of Magnetism and Magnetic Materials 2010 , 322(7) 814-818.

79.   Liu Y, Liu Y, Drew MGB. Correlation between regioselectivity and site charge in propene polymerisation catalysed by metalloceneStructural Chemistry 2009 , 21(1) 21-28.

80.   Wang J, Liu Y, Zhang M, Qiao Y, Xia T. Comparison of the Sol-gel Method with the Coprecipitation Technique for Preparation of Hexagonal Barium FerriteChemical Research in Chinese Universities 2008 , 24(5) 525-528.

81.   Liu Y, Drew MGB, Liu Y. Intermediate ion stability and regioselectivity in propene polymerization using neutral salicyladiminato nickel(II) and palladium(II) complexes as catalystsJournal of Molecular Structure: THEOCHEM 2007 , 809(1-3) 29-37.

82.   Liu Y, Drew MGB, Liu Y. The crucial importance of agostic interactions in intermediates formed in propylene polymerization using neutral salicyladiminato palladium(II) and nickel complexes as catalystsJournal of Molecular Structure: THEOCHEM 2007 , 821(1-3) 30-41.

83.   宁兆娟, 陈野, 刘颖, 张密林, 亓淑艳, 舒畅. 反滴加共沉淀法制备 Gd:YIG 及磁性研究稀土 2007 , 28(02) 43-46.

84.   刘颖, 王敬平, 胡敏, 张密林, 夏天. 溶胶 / 凝胶法制备单磁畴 M 型六角钡铁氧体及磁性应用化学 2007 , 24 1182-1186.

85.   刘颖, 宁兆娟, 谭颖, 王敬平, 张密林. 共沉淀法合成 Y3Fe5O12 及其磁性应用化学 2007 , 24 468-470.

86.   WANG J-P, LI, Ying, HU, Min, ZHANG , Mi-Lin. Effects of different molten-salt on the synthesis of hexagonal barium ferrite. Chinese Journal of Aeronautics 2006 , 16 S206-S209.

87.   刘颖, 王敬平, 谭颖, 张密林, 孟健. 共沉淀 / 熔盐法合成六角片状纳米 BaFe12O19功能材料 2006 , 37 974 - 675.

88.   刘颖, 刘波, 张密林, 刘跃. 酒石酸和氰基二苯基二氢吡唑的高效液相色谱手性分离分析科学学报 2006 , 22 435-437.

89.   刘佳雯, 刘颖, 刘跃. 中性水杨醛亚胺镍催化烯烃聚合反应链引发机理的密度泛函研究分子催化 2006 , 20 51-56.

90.   蒋荣立, 刘颖, 周长春, 郑宏伟, 郑菊花, 高庆宇. 无机及分析化学实验. 中国矿业大学出版社 : 徐州 , 2006 .

91.   Yang Z-D, Liu Y, Liu Y. Regioselectivity Study on Propylene Polymerization Catalyzed by Neutral Salicyladiminato Pd(II) Model Complex with DFT Method结构化学 (Chinese J Struct Chem) 2005 , 24(06) 723-728.

92.   Liu Y, Zhang M, Drew MGB, Yang Z-D, Liu Y. A DFT study of propylene polymerization using neutral salicyladiminato nickel(II) and palladium(II) as catalystsJournal of Molecular Structure: THEOCHEM 2005 , 726(1-3) 277-283.

93.   王骐, 刘颖, 张密林, 刘跃. 二芳基马来酸酐吸收光谱的计算研究光谱学与光谱分析 2005 , 25 685-687.

94.   Hölldobler B, Oldham NJ, Liebig J, Liu Y, David Morgan E. Dufour gland secretion in the harvester ant genus PogonomyrmexChemoecology 2004 , 14(2) 101-106.

95.   杨照地, 刘跃, 刘颖. 水杨亚胺基镍 / 钯配合物催化丙烯聚合电中性机理 --agostic 相互作用的研究哈尔滨师范大学自然科学学报 2004 , 20(02) 83 - 86.

96.   孙丽曼, 刘跃. 硝酮与烯烃的 1,3- 偶极环加成反应区位和立体选择性的量子化学计算研究哈尔滨师范大学自然科学学报 2004 , 20 73-77.

97.   刘颖, 刘跃, 左霞, 吴谊群. 磺化金属萘酞菁聚集倾向的光谱研究光谱学与光谱分析 2004 , 24 652-665.

98.   刘佳雯, 刘颖, 杨小震, 刘跃. 新型 Ni 催化剂催化乙烯聚合的中性机理高分子学报 2004 (3) 333-338.

99.   刘芳, 刘佳雯, 刘颖, 刘跃. 新型 Ni(Ⅱ) 催化剂催化聚合乙烯电中性机理的量子化学研究分子科学学报 2004 , 20 43-48.

100. Liu Y, Wang Q, Liu Y, Yang X-Z. Thermal irreversibility study on the electrocyclic reaction of diaryl maleic anhydrides by density functional calculationsChemical Physics Letters 2003 , 373(3-4) 338-343.

101. LIU Y, LIU Y, Michael DG, LIU J-W. Design and Theoretical Study of Nickel Catalysts for Syndiotactic PolyolefinsChinese Journal of Chemistry 2003 , 21(05) 481–484.

102. Che C-b, Zhang H, Zhang X, Liu Y, Liu B. Ab Intio and Kinetic Study on CH3 Radical Reaction with H2COThe Journal of Physical Chemistry A 2003 , 107(16) 2929-2933.

103. 王骐, 刘跃, 刘颖. 2, 3- 二芳基马来酸酐环合反应机理的计算研究高等学校化学学报 2003 , 24 1869-1872.

104. 刘跃, 杨照地, 刘颖. 水杨亚胺基钯催化聚合丙烯的密度泛函理论研究化学学报 2003 , 61 1528-1532.

105. 刘跃, 王骐, 刘颖. 几种过渡态结构的有效优化方法研究分子科学学报 2003 , 19 181-185.

106. 刘颖, 左霞, 吴谊群, 陈鹏刚, 励蓉, 王振荣. 磺化 2 , 3- 萘酞菁锌( II )、钴( II )的电子吸收光谱和荧光光谱的研究分子科学学报 2003 , 19 172-176.

107. 刘颖, 刘跃. 红收获蚁杜氏腺体细胞壁成分的气相色谱 / 质谱鉴定分析化学 2003 , 31 1228-1230.

108. 刘佳雯, 刘跃. 新型 Ni(II) 催化剂催化乙烯聚合反应机理的密度泛函研究哈尔滨师范大学自然科学学报 2003 , 19 57-60.

109. 刘跃, 王骐, 苏忠民, 刘颖. 用 Gaussian 98 程序计算钪和钛原子价层电子组态能量分子科学学报 2002 , 18 98-102.

110. 刘跃, 刘颖. 红收获蚁信息素的鉴定分析化学 2002 , 30 298-300.

111. 刘跃, 刘佳雯, 杨小震. 新型镍催化剂催化乙烯聚合的阳离子机理物理化学学报 2002 , 18 1068-1070.

112. 刘颖刘跃理论化学. 黑龙江科学技术出版社 : 哈尔滨 , 2002 .

113. Liu Y, Yang X-z, Dai B-q, Su Z-m, Wang Q. Conformation of 1,2-Dimethoxyethane in WaterChemical Research in Chinese Universities 2001 , 17(03) 315-317.

114. 刘跃, 戴柏青. DME 构象的 ADF 研究分子科学学报 2000 , 16 110-113.

115. 刘颖, 左霞, 吴谊群, 朱清桃, 陈耐生, 宋瑛林, et al. 四溴 -2 , 3- 萘酞菁锌 (II) 的合成及非线性光线幅特性应用化学 2000 , 17 569-571.

116. 刘颖 , 杜华 , 刘跃 . 逆反应一定使反应物的浓度增加吗 . 哈尔滨师范大学自然科学学报 2000 , 16 52-57.

117. 宋瑛林 , 王玉晓 , 方光宇 , 常宏 , 吴谊群 , 刘颖 , et al. 萘酞菁锌化合物的光限幅特性研究 . 光学技术 1999 (4) 76-77-81.

118. 宋瑛林 , 王玉晓 , 董鉴奇 , 李俊庆 , 吴谊群 , 刘颖 , et al. 高可见光透射率的溴取代萘酞菁锌化合物的光限幅特性研究 . 中国激光 1999 , 26 325-326.

119. SONG Y, WANG Y, LI J, FANG G, YANG X, Wu Y, LIU Ying, et al. Study on Optical Limiting Properties of a Novel Bromizated NaphthalocyanineProceedings of SPIE, Photorefractive Materials: Phenomena and Related Applications II 1998 , 3554 241-245.

120. 刘颖, 刘跃. 影响光谱及能级的因素牡丹江师院学报 1998 (1) 39 - 41.

121. Yang X, Liu Y, Hsu S. Conformation and chain packing structures of poly-(p-phenylene benzobisthiazole) by molecular simulationChinese Journal of Polymer Science 1997 , 15(04) 295-304.

122. 刘跃, 杨小震. 分子模拟法研究高性能树脂 ── 聚苯撑苯并二噻唑分子链的构象与堆砌化学通报 1996 (4) 32-34.

123. 刘跃, 贺子如, 刘颖平衡理论. 化学工业出版社 : 北京 , 1995 .

124. . 刘跃, 赵成大, 黄敬安. 双桥反应机理的从头计算研究物理化学学报 1994 , 10 154-158.

125. 刘颖, 杨小震, 刘跃. 双桥反应及其应用化学通报 1994 (10) 20-22.

126. 刘颖, 刘跃, 杨小震. 化学平衡中的极值化学通报 1994 (03) 51 - 54.

127. 刘颖, 刘跃. 论反应商和反应进程的关系牡丹江师范学院学报 1994 (1) 19 - 21.

128. Liu Y, Yang XZ. A Study of Packing Structure of Poly(p-Phenylene Benzobisthiaole) by Molecular SimulationChinese Chemical Letters 1993 , 4(09) 779-782.

129. 刘跃, 刘颖, 萧泰. 一类 Narcissistic 反应过渡态的优化化学研究与应用 1993 , 5 97-99.

130. 刘跃定态波函数牡丹江师院学报 1992 (1) 37 - 38.



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