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狂賀  恭喜李嘉甄老師 榮獲2019年第十七屆有庠科技論文獎！！

 

狂賀  恭喜本實驗室 榮獲2018年光寶創新獎「技術創新組」潛力賞！！

 

狂賀  恭喜本實驗室 榮獲2017年光寶創新獎「技術創新組」金賞！！

 

狂賀  恭喜本實驗室 榮獲2017年材料創新獎 第二名！！

 

2022

 

恭賀實驗室新發表論文榮登ACS Applied Electronic Materials期刊封面

 

 

2021

 

恭賀陳品妤同學 碩士班甄試錄取國立清華大學 材料科學與工程學系碩士班

恭賀陳品妤同學 碩士班甄試錄取國立台灣大學 材料科學與工程學系碩士班

 

 

2020

 

恭賀卓泉勝同學 榮獲109年度中技社科技獎學金

恭賀余蕙均同學 榮獲108年度材料年會論文競賽優等獎！！

恭賀施宣如同學 榮獲108年度科技部大專生專題研究創作獎！！

恭賀余俊宏同學 通過109年度大專生專題研究計畫

 

恭賀施宣如同學 碩士班甄試錄取國立清華大學 材料科學與工程學系碩士班

恭賀郭家和同學 碩士班甄試錄取國立台灣大學 材料科學與工程學系碩士班

恭賀趙崇名同學 碩士班甄試錄取國立清華大學 奈米工程及微系統研究所碩士班

恭賀吳忠俊同學 碩士班甄試錄取國立台北科技大學 材料工程學系碩士班

 

 

2019

 

恭賀李嘉甄老師 榮獲2019年第十七屆有庠科技論文獎！！！

恭賀李嘉甄老師 榮獲2019年臺北科大院傑出研究獎！！！

 

恭賀鄭暐儒同學 榮獲107年度科技部大專生專題研究創作獎！！

恭賀施宣如同學 通過108年度大專生專題研究計畫

恭賀黃凌萱同學 榮獲2018年材料年會論文競賽優等獎

 

 

2018

 

恭賀實驗室新發表論文榮登ChemElectroChem期刊封面

恭賀實驗室研究成果發表於高品質期刊 Materials Horizons (SCI, IF 14.356, Rank 17/293, 5.8%)

恭賀實驗室新發表論文榮登J. Colloid Interface Sci.期刊封面

恭賀李嘉甄老師 榮獲2018年臺北科大校傑出研究獎！！！

恭賀李嘉甄老師 榮升臺北科大特聘教授！！！

 

恭喜陳麒安、徐宏睿同學 榮獲2018年材料創新獎佳作！！！

恭喜宋亞峻、徐宏睿、余蕙均同學 榮獲2018年光寶創新獎「技術創新組」潛力賞！！！

恭賀陳 毅同學 碩士班甄試錄取國立清華大學 工程與系統科學系碩士班

恭賀鄭暐儒同學 碩士班甄試錄取國立清華大學 材料科學與工程學系碩士班

恭賀黃凌萱同學 碩士班甄試錄取國立清華大學 材料科學與工程學系碩士班

恭賀陳家尉同學 榮獲2018年陶瓷年會論文競賽碩士組佳作

恭賀鄭暐儒同學 榮獲2018年陶瓷年會論文競賽大專生組第二名

 

 

2017

 

恭賀實驗室研究成果發表於高品質期刊 Journal of Materials Chemistry A (SCI, IF 9.931, Rank 6/97, 6.1%)

恭喜本實驗室 榮獲2017年材料創新獎 第二名！！

恭喜張家豪同學 榮獲2017年光寶創新獎「技術創新組」金賞！！

恭賀李嘉甄老師 榮獲2017年臺北科大院傑出研究獎！！！

 

恭賀陳麒安同學 榮獲2017年陶瓷年會論文競賽大專生組第二名

恭賀張家豪同學 榮獲2017年陶瓷年會論文競賽碩士組入圍

恭賀楊庭懿同學 碩士班甄試錄取國立台灣大學 材料科學與工程學系碩士班

恭賀劉魏溢同學 碩士班考試錄取國立成功大學 材料科學與工程學系碩士班

 

 

2016

 

恭賀實驗室研究成果發表於高品質期刊 Chemistry of Materials (SCI, IF 9.466, Rank 15/271, 5.5%)

恭賀鄒侑儒同學 榮獲2016年材料創新獎入圍決賽

恭賀陳嬿昕同學 碩士班考試錄取國立台灣大學 材料科學與工程學系碩士班

恭賀陳致賢同學 榮獲2016年光寶創新獎技術組入圍決賽

恭賀李嘉甄 老師榮獲105年陶瓷年會傑出服務獎！！

 

 

2015

 

恭賀郭銘書同學 榮獲103年度陶業年會論文競賽奈米陶瓷組第二名

恭賀張家豪同學 碩士班甄試錄取國立台北科技大學 材料工程學系碩士班

恭賀劉柏亨同學 碩士班甄試錄取國立清華大學 奈米工程與微系統學系碩士班

恭賀王崇軒同學 碩士班甄試錄取國立台灣大學 材料科學與工程學系碩士班

 

 

2014

 

恭賀董芝安同學 碩士班甄試錄取國立清華大學 材料工程學系碩士班

恭賀陳柏瑋同學 碩士班甄試錄取國立清華大學 奈米工程與微系統學系碩士班

恭賀王霆鈞同學 碩士班考試錄取國立台灣大學 材料科學與工程學系碩士班

 

 

2013

 

恭賀李嘉甄老師 榮獲2013年臺北科大院傑出研究獎！！！

恭賀董芝安同學 榮獲金手獎第三名

 

恭賀蔡志辰同學 碩士班考試錄取國立清華大學 工程與系統科學系碩士班

恭賀洪靚軒同學 碩士班考試錄取國立清華大學 工程與系統科學系碩士班

恭賀黃俞碩同學 碩士班考試錄取國立中央大學 材料科學與工程學系碩士班

 

 

2012

 

恭賀李嘉甄老師 榮獲2012年臺北科大院傑出研究獎！！！

 

恭賀蔡志辰同學 申請國科會大專生參與專題研究計畫審查通過

恭賀蘇凡均同學 碩士班考試錄取國立中央大學 化學工程與材料工程學系碩士班

恭賀紀卉彥同學 碩士班考試錄取國立中央大學 化學工程與材料工程學系碩士班

 

 

2011

 

恭賀林書緯同學 碩士班甄試錄取國立交通大學 加速器光源科技與應用碩士學位學程

 

 

2010

 

恭賀程羿穆同學 榮獲99年度國科會專題研究計畫研究創作獎！！

恭賀楊庭喻同學 參與礦冶年會得到佳作

恭賀劉俊甫同學 申請國科會大專生參與專題研究計畫審查通過

恭賀劉家佩同學 申請國科會大專生參與專題研究計畫審查通過

恭賀程羿穆同學 申請國科會大專生參與專題研究計畫審查通過

恭賀程羿穆同學 碩士班甄試錄取國立台灣大學 材料科學與工程研究所

恭賀劉家珮同學 碩士班甄試錄取國立中央大學 材料科學與工程研究所

恭賀劉俊甫同學 碩士班甄試錄取國立清華大學 奈米工程與微系統研究所

恭賀楊庭喻同學 碩士班甄試錄取國立成功大學 資源工程研究所

 

 

2009

 

恭賀顏秉生同學 申請國科會大專生參與專題研究計畫審查通過

恭賀彭杏威同學 榮獲98年中華民國陶業研究學會海報論文優等獎碩士組第一名

恭賀顏秉生同學 碩士班甄試錄取國立清華大學 材料科學與工程研究所

恭賀王雅慧同學 碩士班甄試錄取國立台北科技大學 材料科學與工程研究所

 

 

2008

 

恭賀潘昭璇同學 申請國科會大專生參與專題研究計畫審查通過

恭賀張嘉芝同學 申請國科會大專生參與專題研究計畫審查通過

恭賀潘昭璇同學 碩士班甄試錄取國立清華大學 材料科學與工程研究所

恭賀賴淑萍同學 碩士班甄試錄取國立清華大學 工程與系統科學研究所

恭賀林宣萱同學 碩士班甄試錄取國立清華大學 工程與系統科學研究所

恭賀張嘉芝同學 碩士班甄試錄取國立中興大學 材料科學與工程研究所

 

 

2007

 

恭賀朱永如同學 申請國科會大專生參與專題研究計畫審查通過

恭賀邱祺瑾同學 申請國科會大專生參與專題研究計畫審查通過

恭賀廖為盛、邱祺瑾同學 榮獲96年中華民國陶業研究學會海報論文優等獎

恭賀朱永如同學 碩士班甄試錄取國立清華大學 材料科學與工程研究所

恭賀粘志鴻同學 碩士班甄試錄取國立中山大學 材料與光電工程研究所

恭賀邱祺瑾同學 碩士班甄試錄取國立中山大學 材料與光電工程研究所

 

 

2006

 

恭賀董怡伶同學 申請國科會大專生參與專題研究計畫審查通過

恭賀董怡伶同學 榮獲95年中國材料科學會壁報論文優等獎

恭賀董怡伶同學 碩士班甄試錄取國立清華大學 材料科學與工程研究所

恭賀彭杏威同學 碩士班甄試取國立台北科技大學 材料科學與工程研究所

 

 

 

 

2022

 

1. Ching-Ping Hsiao, Jhewn-Kuang Chen and Chia-Chen Li*

“Microencapsulated Liquid Metals for the Autonomous Restoration of In-Mold Electronic Circuits,"

ACS Appl. Electron. Mater., 4, 936–945, 2022. (SCI, IF 8.00, Rank 95/273, 34.8%)

 

 

2021

6. Sheng-Yu He and Chia-Chen Li*

“Advantages of Using Carbon Fabric over Cu Foil as Conductive Matrix for Anodes of Micro- and Nano-Sized Si,"

Materials Research Bulletin, 148, 111690, 2021. (SCI, IF 4.641, Rank 109/334, 32.49%)

 

5. Sireesha Pedaballi and Chia-Chen Li*

“Aqueous Processed Ni-Rich Li(Ni_0.8Co_0.1Mn_0.1)O₂ Cathodes Along with Water-Based Binders and a Carbon Fabric as 3-D Conductive Host,"

Journal of The Electrochemical Society, 168, 120538, 2021. (SCI, IF 4.316, Rank 5/21, 23.81%)

 

4. Sireesha Pedaballi and Chia-Chen Li*

“Using conductive carbon fabric to fabricate binder-free Ni-rich cathodes for Li-ion batteries,"

International Journal of Energy Research, 45, 1–9, 2021. (SCI, IF 5.164, Rank 1/34, 2.94%)

 

3. Sheng-Yu He, Chuan-Sheng Cho, Jhewn-Kuang Chen and Chia-Chen Li*

“Good Structural Stability of Si Anodes Achieved through Dispersant Addition and Use of Carbon Fabric as Conductive Framework,"

Journal of The Electrochemical Society, 168, 060517, 2021. (SCI, IF 4.316, Rank 5/21, 23.81%)

 

2. Chun-Hung Yu, Chuan-Sheng Cho, Chia-Chen Li*

“Well-Dispersed Garnet Crystallites for Applications in Solid-State Li–S Batteries,"

ACS Appl. Mater. Interfaces, 13, 11995-12005, 2021. (SCI, IF 8.758, Rank 33/314, 10.5%)

 

1. Hung-Jui Hsu, Chia-Chen Li*

“TiO₂-based microsphere with large pores to improve the electrochemical performance of Li-ion anodes,"

Ceramics International, 47, 12038-12046, 2021. (SCI, IF 3.830, Rank 2/28, 7.14%)

 

 

2020

 

11. Ta-Li Hsieh, Chia-Chen Li*, Po-Ching Lin, Ya-Chu Hsu

“Encapsulating Well-Dispersed Carbon Nanoparticles for Applications in the Autonomous Restoration of Electronic Circuits,"

ACS Appl. Mater. Interfaces, 12, 38690-38699, 2020. (SCI, IF 8.758, Rank 33/314, 10.5%)

 

10. Sireesha Pedaballi, Chia-Chen Li*

“Effects of surface modification and organic binder type on cell performance of water-processed Ni-rich Li(Ni_0.8Co_0.1Mn_0.1)O₂ cathodes,"

J. Power Sources, 472, 228552, 2020. (SCI, IF 8.247, Rank 10/112, 8.92%)

 

9. Chuan-Sheng Cho, Jin-Yu Chang, Chia-Chen Li*

“Highly symmetric gigaporous carbon microsphere as conductive host for sulfur to achieve high areal capacity for lithium–sulfur batteries,"

J. Power Sources, 457, 227818, 2020. (SCI, IF 8.247, Rank 10/112, 8.9%)

 

8. Chung-Chun Wu, Chia-Chen Li*

“Distribution Uniformity of Water-Based Binders in Si Anodes and the Distribution Effects on Cell Performance,"

ACS Sustainable Chem. Eng., 8, 6868-6876, 2020. (SCI, IF 7.632, Rank 8/143, 5.59%)

 

7. Tsung-Ming Chao, Ta-Li Hsieh, Shinn-Jen Chang, Cha-Wen Chang, Chia-Chen Li*

“New Brush Copolymers as an Effective Dispersant for Stabilizing Concentrated Suspensions of Silver Nanoparticles,"

Langmuir, 36, 3377-3385, 2020. (SCI, IF 3.557, Rank 60/177, 33.9%)

 

6. Jia-He Kuo, Chia-Chen Li*

“Water-Based Process to the Preparation of Nickel-Rich Li(Ni_0.8Co_0.1Mn_0.1)O₂ Cathode,"

Journal of The Electrochemical Society, 167, 100504, 2020. (SCI, IF 3.721, Rank 5/21, 23.8%)

 

5. Tsung-Ming Chao, Shinn-Jen Chang, Cha-Wen Chang, Chia-Chen Li*

“Using a Brush Copolymer as Efficient Dispersant for the Preparation of Highly Stabilized Ag Nanoparticles in Aqueous Suspensions,"

AOCS Journal of Surfactants and Detergents, 23, 841-851, 2020. (SCI, IF 1.654, Rank 37/71, 52.1%)

 

4. Xin-Rui Wu, Chun-Hung Yu, Chia-Chen Li*

“Carbon-encapsulated gigaporous microsphere as potential Si anode-active material for lithium-ion batteries,"

Carbon, 160, 255-264, 2020. (SCI, IF 8.821, Rank 32/314 , 10.2%)

 

3. Hsuan-Ju Shih, Jin-Yu Chang, Chuan-Sheng Cho, Chia-Chen Li*

“Nano-carbon-fiber-penetrated sulfur crystals as potential cathode active material for high-performance lithium–sulfur batteries,"

Carbon, 159, 401-411, 2020. (SCI, IF 8.821, Rank 32/314, 10.2%)

 

2. Changyong Liu, Deng Yan, Jianwei Tan, Zhuokeng Mai, Zhixiang Cai, Yuhong Dai, Mingguang Jian, Pei Wang, Zhiyuan Liu, Chia-Chen Li, Changshi Lao*, Zhangwei Chen*

“Development and experimental validation of a hybrid selective laser melting and CNC milling system,"

Additive Manufacturing, 36, 101550, 2020. (SCI, IF 7.002, Rank 3/50, 6%)

 

1. Yu-Ting Zhang, Hui-Chun Yu, Ming-Cheng Shen, Yuh-Tyng Chern, Chia-Chen Li*

“Synthesis and application of self-healing microcapsules containing curable glue,"

Materials Chemistry and Physics, 240, 122161, 2020. (SCI, IF 3.408, Rank 115/314, 36.6%)

 

 

2019

 

 

6. Hui-Chun Yu, Yu-Ting Zhang, Ming-Jia Wang, Chia-Chen Li*

“Dispersion of Poly(urea-formaldehyde)-Based Microcapsules for Self-Healing and Anticorrosion Applications,"

Langmuir, 35, 7871-7878, 2019. (SCI, IF 3.557, Rank 60/177, 33.9%)

 

5. Sireesha Pedaballi, Chia-Chen Li*, Ya-Jun Song

“Dispersion of microcapsules for the improved thermochromic performance of smart coatings,"

RSC Advances, 42, 24175-24183, 2019. (SCI, IF 3.049, Rank 73/177, 41.24%)

 

4. Chuan-Sheng Cho, Hsuan-Ju Shih, Chia-Chen Li*

“Facile Synthesis of Hierarchical Sulfur Composites for Lithium–Sulfur Batteries,"

ChemElectroChem, 6, 2438-2447, 2019. (SCI, IF 4.154, Rank 10/27, 37%)

 

3. Tsung-Chieh Kuo, Chun-Yu Chiou, Chia-Chen Li, Jyh-Tsung Lee*

“In situ cross-linked poly(ether urethane) elastomer as a binder for high-performance Si anodes of lithium-ion batteries,"

Electrochimica Acta, 327, 135011, 2019. (SCI, IF 6.215, Rank 5/27, 18.5%)

 

2. Ling-Hsuan Huang, Chia-Chen Li*

“Effects of interactions between binders and different-sized silicons on dispersion homogeneity of anodes and electrochemistry of lithium-silicon batteries,"

J. Power Sources, 409, 38-47, 2019. (SCI, IF 8.247, Rank 10/112, 8.9%)

 

1. Jia-Hao Jhang, Shinn-Jen Chang, Sireesha Pedaballi, Chia-Chen Li*

“A new porous structure with dispersed Nano-TiO₂ in a three-dimensional carbon skeleton for achieving high photocatalytic activity,"

Microporous Mesoporous Mater., 276, 62-67, 2019. (SCI, IF 4.551, Rank 13/71, 18.3%)

 

 

2018

 

9. Chi-An Chen, Chia-Chen Li*, Chi-Hsien Chen

“A smart hemicapsule with multiple dynamic functions,"

Materials Horizons, 5, 1092-1099, 2018. (SCI, IF 14.356, Rank 17/293, 5.8%)

 

8. Wei-Ju Cheng, Shinn-Jen Chang, Chuan-Sheng Cho, Chia-Chen Li*

“Using Poly(4-styrene sulfonic acid) to Disperse Graphene for Application in Lithium-Sulfur Batteries,"

ChemElectroChem, 5, 3835-3840, 2018. (SCI, IF 3.975, Rank 9/26, 34.6%) (Invited cover image)

 

7. Rupesh Rohan, Tsung-Chieh Kuo, Chun-Yu Chiou, Yu-Lung Chang, Chia-Chen Li, Jyh-Tsung Lee*

“Low-cost and sustainable corn starch as a high-performance aqueous binder in silicon anodes via in situ cross-linking,"

J. Power Sources, 396, 459-466, 2018. (SCI, IF 7.467, Rank 11/103, 10.6%)

 

6. Ling-Hsuan Huang, Di Chen, Chia-Chen Li*, Yu-Lung Chang, Jyh-Tsung Lee

“Dispersion Homogeneity and Electrochemical Performance of Si Anodes with the Addition of Various Water-Based Binders,"

J. Electrochem. Soc., 165, A2239-A2246, 2018. (SCI, IF 3.120, Rank 4/20, 20.0%)

 

5. Wei-Ju Cheng, Chuan-Sheng Cho, Chia-Chen Li*,

“Gelatinization of Guar Gum and Its Effects on the Dispersion and Electrochemistry of Lithium-Sulfur Batteries,"

J. Electrochem. Soc., 165, A2058-A2060, 2018. (SCI, IF 3.120, Rank 4/20, 20.0%)

 

4. Ren-Mian Chin, Shinn-jen Chang, Chia-Chen Li*, Cha-Wen Chang, Ruo-Han Yu,

“Preparation of highly dispersed and concentrated aqueous suspensions of nanodiamonds using novel diablock dispersants,"

J. Colloid Interface Sci., 520, 119-126, 2018. (SCI, IF 6.361, Rank 29/148, 19.5%) (Invited cover image)

 

3. Hsin-Yi Tsai, Shinn-Jen Chang, Ting-Yi Yang, Chia-Chen Li*,

“Distinct dispersion stability of various TiO₂ nanopowders using ammonium polyacrylate as dispersant,”

Ceram. Int., 44, 5131-5138, 2018. (SCI, IF 3.450, Rank 2/28, 7.1%)

 

2. Chia-Chen Li*, Ming-Jyun Li, Yung-Pin Huang,

“Dispersion of aluminum-doped zinc oxide nanopowder with high solid content in ethylene glycol,”

Powder Technol., 327, 1-8, 2018. (SCI, IF 3.413, Rank 32/138, 23.1%)

 

1. Chi-An Chen, Chia-Chen Li*,

“Microencapsulating inorganic and organic flame retardants for the safety improvement of lithium-ion batteries,"

Solid State Ionics, 323, 56-63, 2018. (SCI, IF 2.886, Rank 24/68, 35.2%)

 

 

2017

 

13. Yun-Ju Lan, Shinn-Jen Chang, Chia-Chen Li*,

“Synthesis of Conductive Microcapsules for Fabricating Restorable Circuits,”

J. Mater. Chem. A, 5, 25583–25593, 2017. (SCI, IF 9.931, Rank 6/97, 6.1%)

 

12. Pei-Hsuan Huang, Shinn-Jen Chang, Chia-Chen Li*,

“Encapsulation of flame retardants for application in lithium-ion batteries,”

J. Power Sources, 338, 82-90, 2017. (SCI, IF 6.395, Rank 2/29, 6.9%)

 

11. Chia-Chen Li*, Dzu-How Yu, Shinn-Jen Chang, Jia-Wei Chen,

“New Approach for the Synthesis of Nanozirconia Fortified Microcapsules,”

Langmuir, 33, 5843–5851, 2017. (SCI, IF 3.789, Rank 61/285, 21.4%)

 

10. Chia-Chen Li*, Shinn-Jen Chang, Chi-Wei Wu, Cha-Wen Chang, Ruo-Han Yu,

“Newly designed diblock dispersant for powder stabilization in water-based suspensions,”

J. Colloid Interface Sci., 506, 180–187, 2017. (SCI, IF 4.233, Rank 35/145, 23.9%)

 

9. Pei-Hsuan Huang, Shinn-Jen Chang, Chia-Chen Li*, Chi-An Chen,

“Boehmite-based Microcapsules as Flame-retardants for lithium-ion batteries,”

Electrochim. Acta, 228, 597-603, 2017. (SCI, IF 4.798, Rank 4/29, 13.8%)

 

8. Chia-Chen Li*, Shinn-Jen Chang, Chi-Wei Wu, Cha-Wen Chang,

“Poly(methacrylate)-derived Diblock Dispersant for TiO₂ in Aqueous Suspensions,”

J. Am. Ceram. Soc., 100, 4961–4964, 2017. (SCI, IF 2.841, Rank 3/26, 11.5%)

 

7. Chia-Chen Li*, Ming-Jyun Li, Yung-Pin Huang,

“Dispersion of aluminum-doped zinc oxide nanopowder in non-aqueous suspensions,”

J. Am. Ceram. Soc., 100, 5020–5029, 2017. (SCI, IF 2.841, Rank 3/26, 11.5%)

 

6. Chia-Chen Li*, Wei-I Liu, Yen-Shin Chen,

“Efficient Dispersants for the Dispersion of Gallium Zinc Oxide Nanopowder in Aqueous Suspensions,”

J. Am. Ceram. Soc., 100, 920–928, 2017. (SCI, IF 2.841, Rank 3/26, 11.5%)

 

5. Ting-Yi Yang, Shinn-Jen Chang, Chia-Chen Li*, and Pei-Hsuan Huang,

“Selectivity of Hydrophilic and Hydrophobic TiO₂ for Organic-based Dispersants,”

J. Am. Ceram. Soc., 100, 56–64, 2017. (SCI, IF 2.841, Rank 3/26, 11.5%)

 

4. Chia-Chen Li*, Jia-Hao Jhang, Hsin-Yi Tsai, Yung-Pin Huang,

“Water-soluble Polyethylenimine as an Efficient Dispersant for Gallium Zinc Oxide Nanopowder in Organic-based Suspensions,”

Powder Technol., 305, 226-231, 2017. (SCI, IF 2.759, Rank 26/135, 19.2%)

 

3. Chia-Chen Li*, Chi-An Chen, Meng-Fu Chen,

“Gelation Mechanism of Organic Additives with LiFePO₄ in the Water-based Cathode Slurries,”

Ceram. Int., 43, S765–S770, 2017. (SCI, IF 2.758, Rank 3/27, 11.1%)

 

2. Chia-Chen Li*, Shinn-Jen Chang, Chi-An Chen,

“Effects of sp²- and sp³-carbon coatings on dissolution and electrochemistry of water-based LiFePO₄ cathodes,”

J. Appl. Electrochem., 47 [9] 1065-1072, 2017. (SCI, IF 2.235, Rank 15/29, 51.7%)

 

1. Hoxin Yen, Rupesh Rohan, Chun-Yu Chiou, Chang-Ju Hsieh, Satish Bolloju, Chia-Chen Li, Yi-Fei Yang, Chi-Wi Ong, Jyh-Tsung Lee*,

“Hierarchy concomitant in situ stable iron(II)−carbon source manipulation using ferrocenecarboxylic acid for hydrothermal synthesis of LiFePO₄ as high-capacity battery cathode,”

Electrochim. Acta, 253, 227–238, 2017. (SCI, IF 4.798, Rank 4/29, 13.7%)

 

 

2016

 

6. Chia-Chen Li*, Sheng Yang, Yu-Ju Tsou, Jyh-Tsung Lee, Chang-Ju Hsieh,

“Newly Designed Copolymers for Fabricating Particles with Highly Porous Architectures,”

Chem. Mater., 28, 6089–6095, 2016. (SCI, IF 9.466, Rank 15/271, 5.5%)

 

5. J. J. Yang, C. C. Li, Y. F. Yang, C. Y. Wang, C. H. Lin, J. T. Lee*,

“Superparamagnetic core–shell radical polymer brush as efficient catalyst for oxidation of alcohols to aldehydes and ketones,”

RSC Adv., 6, 63472-63476, 2016. (SCI, IF 3.289, Rank 49/163, 30%)

 

4. R. Rohan; T. C. Kuo, J. H. Lin, Y. C. Hsu, C. C. Li, J. T. Lee*,

“Dinitrile–Mononitrile-Based Electrolyte System for Lithium-Ion Battery Application with theechanism of Reductive Decomposition of Mononitriles,”

J. Phys. Chem. C, 120, 6450–6458, 2016. (SCI, IF 4.509, Rank 40/271, 14.7%)

 

3. M.S. Kuo, S.J. Chang, P.H. Hsieh, Y.C. Huang, C.C. Li*,

“Efficient Dispersants for TiO₂ Nanopowder in Organic Suspensions,”

J. Am. Ceram. Soc., 99, 445-451, 2016. (SCI, IF 2.787, Rank 2/27, 7.4%)

 

2. F.Y. Tsai, J.H. Jhang, H.W. Hsieh, C.C. Li*,

“Dispersion, Agglomeration, and Gelation of LiFePO₄ in Water-based Slurry,”

J. Power Sources, 310, 45-53, 2016. (SCI, IF 6.333, Rank 2/27, 7.4%)

 

1. T.H. Ho, S.J. Chang, C.C. Li*,

“Effect of Surface Hydroxyl Groups on the Dispersion of Ceramic Powders,”

Mater. Chem. Phys., 172, 1-5, 2016. (SCI, IF 2.101, Rank 97/271, 35.7%)

 

 

Before 2015

 

G.W. Lai, S.J. Chang, J.T. Lee, H. Liu, C.C. Li*,

“Conductive Microcapsules for Self-healing Electric Circuits,”

RSC Adv., 5, 104145-104148, 2015. (SCI, IF 3.289, Rank 49/163, 30%)

 

Shinn-Jen Chang, Chih-An Tung, Bo-Wei Chen, Yi-Chun Chou, Chia-Chen Li*,

“Synthesis of Non-oxidative Copper Nanoparticles,”

RSC Adv., 3, 24005–24008, 2013. (SCI, IF 3.289, Rank 49/163, 30%)

 

Jyh-Cheng Tsai, Feng-Yen Tsai, Chih-An Tung, Han-Wei Hsieh, Chia-Chen Li*,

“Gelation or dispersion of LiFePO₄ in water-based slurry?”

J. Power Sources, 241, 400-403, 2013. (SCI, IF 6.333, Rank 2/27, 7.4%)

 

Chia-Chen Li*, Ya-Whei Wang,

“Importance of binder compositions to the dispersion and electrochemical properties of water-based LiCoO₂ cathodes,”

J. Power Sources, 227, 204-210, 2013. (SCI, IF 6.333, Rank 2/27, 7.4%)

 

Yi-Ping Liang, Chia-Chen Li, Wen-Jing Chen, Jyh-Tsung Lee*,

“Hydrothermal synthesis of lithium iron phosphate using pyrrole as an efficient reducing agent,”

Electrochim. Acta, 87, 763-769, 2013. (SCI, IF 4.803, Rank 3/27, 11.1%)

 

Chia-Chen Li*, Chung-Hsuan Chang,

“Gelation and degelation of PVA in aqueous BaTiO₃ slurries,”

J. Am. Ceram. Soc., 96, 436–441, 2013. (SCI, IF 2.787, Rank 2/27, 7.4%)

 

Chia-Chen Li*, Shinn-Jen Chang, Fan-Jun Su, Shu-Wei Lin, Yi-Chun Chou,

“Effects of capping agents on the dispersion of silver nanoparticles,”

Colloids Surf. A, 419, 209-215, 2013. (SCI, IF 2.760, Rank 56/144, 38.8%)

 

Chia-Chen Li*, Yu-Sheng Lin,

“Interactions between organic additives and active powders inwater-based lithium iron phosphate electrode slurries,”

J. Power Sources, 220, 413-421, 2012. (SCI, IF 6.333, Rank 2/27, 7.4%)

 

Yen-Yao Cheng, Chia-Chen Li, Jyh-Tsung Lee*,

“Electrochemical behavior of organic radical polymer cathodes in organic radical batteries with N-butyl-N-methylpyrrolidinium bis(trifluoromethylsulfonyl)imide ionic liquid electrolytes,”

Electrochim. Acta, 66, 332–339, 2012. (SCI, IF 4.803, Rank 3/27, 11.1%)

 

C.C. Li*, Y.H. Wang,

“Binder Distributions in Water-based and Organic-based LiCoO₂ Electrode Sheets and Their Effects on Cell Performance,”

J. Electrochem. Soc., 158, A1361-A1370, 2011. (SCI, IF 3.014, Rank 2/18, 11.1%)

 

Hsiao-Chien Lin, Chia-Chen Li, Jyh-Tsung Lee*,

“Nitroxide polymer brushes grafted onto silica nanoparticles as cathodes for organic radical batteries,”

J. Power Sources, 196, 8096-8103, 2011. (SCI, IF 6.333, Rank 2/27, 7.4%)

 

Chia-Chen Li*, Ya-Hui Wang, Ting-Yu Yang,

“Effects of Surface-coated Carbon on the Chemical Selectivity for Water-Soluble Dispersants of LiFePO₄,”

J. Electrochem. Soc., 158, A828-A834, 2011. (SCI, IF 3.014, Rank 2/18, 11.1%)

 

Chia-Chen Li*, Shinn-Jen Chang, Ming-Yu Tai,

“Effects of Compositional Impurity on Surface Chemistry of TiO₂Nanopowder and its Chemical Interactions with Dispersants,”

Mater. Chem. Phys., 131, 400-405, 2011. (SCI, IF 2.101, Rank 97/271, 35.7%)

 

Chia-Chen Li*, Shinn-Jen Chang, Ming-Yu Tai,

“Surface Chemistry and Dispersion Property of TiO₂ Nanoparticles,”

J. Am. Ceram. Soc., 93, 4008–4010, 2010. (SCI)

 

Chia-Chen Li*, Yi-Chen Lee, Yi-Mu Cheng,

“Effects of Interactions Among BaTiO₃, PVA, and B2O3 on the Rheology of Aqueous BaTiO₃ Suspensions,”

J. Am. Ceram. Soc., 93, 3049–3051, 2010. (SCI)

 

Jyh-Tsung Lee*, Fu-Ming Wang, Chin-Shu Cheng, Chia-Chen Li, Chun-Hao Lin,

“Low-temperature atomic layer deposited Al2O3 thin film on layer structure cathode for enhanced cycleability in lithium-ion batteries,”

Electrochim. Acta, 55, 4002–4006, 2010. (SCI)

 

Chia-Chen Li*, Chun-Lung Huang,

“Preparation of Clear Colloidal Solutions of Detonation Nanodiamond in Organic Solvents,”

Colloids Surf. A, 353, 52–56, 2010. (SCI)

 

Chia-Chen Li*, Xing-Wei Peng, Jyh-Tsung Lee, Fu-Ming Wang,

“Using Poly(4-Styrene Sulfonic Acid) to Improve the Dispersion Homogeneity of Aqueous-Processed LiFePO4 Cathodes,”

J. Electrochem. Soc., 157, A517-A520, 2010. (SCI)

 

Shinn-Jen Chang, Chia-Chen Li*, Wei-Sheng Liao, Jyh-Tsung Lee,

“Efficient Hydroxylation of BaTiO3 Nanoparticles by Using Hydrogen Peroxide,”

Colloids Surf. A, 361, 143–149, 2010. (SCI)

 

Shinn-Jen Chang, Wei-Sheng Liao, Ci-Jin Ciou, Jyh-Tsung Lee, Chia-Chen Li*,

“ An Efficient Approach to Derive Hydroxyl Groups on the Surface of Barium Titanate Nanoparticles to Improve Its Chemical Modification Ability, ”

J. Colloid Interface Sci., 329, 300–305, 2009. (SCI)

 

Jyh-Tsung Lee, Yung-Ju Chu, Xing-Wei Peng, Fu-Ming Wang, Chang-Rung Yang, Chia-Chen Li*,

“ A novel and efficient water-based composite binder for LiCoO2 cathodes in lithium-ion batteries, ”

J. Power Sources, 173, 985–989, 2007. (SCI)

 

Jyh-Tsung Lee, Yung-Ju Chu, Fu-Ming Wang, Chang-Rung Yang, Chia-Chen Li*,

“ Aqueous processing of lithium-ion battery cathodes using hydrogen peroxide-treated vapor-grown carbon fibers for improvement of electrochemical properties, ”

J. Mater. Sci., 42, 10118-10123, 2007. (SCI)

 

J. T. Lee*, M. S. Wu, F. M. Wang, H. W. Liao, C. C. Li, S. M. Chang, C. R. Yang,

“ Gel Polymer Electrolytes Prepared by in situ Atom Transfer Radical Polymerization at Ambient Temperature, ”

J. Electrochem. Solid-State Lett. 10, A97, 2007. (SCI)

 

Chia-Chen Li*, Jen-Lien Lin, Shu-Jiuan Huang, Jyh-Tsung Lee, Ci-Huei Chen,

“ A New and Acid-exclusive Method for Dispersing Carbon Multi-Walled Nanotubes in Aqueous Suspensions, ”

Colloids Surf. A, 297, 275-281, 2007. (SCI)

 

Jen-Chieh Liu, Jau-Ho Jean*, Chia-Chen Li,

“ Dispersion of nano-sized g-alumina powder in non-polar solvents, ”

J. Am. Ceram. Soc., 89, 882-887, 2006. (SCI)

 

Chia-Chen Li*, Jyh-Tung Lee, Xing-Wei Peng,

“ Improvements of Dispersion Homogeneity and Cell Performance of Aqueous-Processed LiCoO2 Cathodes by Using Dispersant of PAA-NH4, ”

J. Electrochem. Soc., 153, A809-A815, 2006. (SCI)

 

Chia-Chen Li*, Jyh-Tsung Lee, Yi-Ling Tung,

“ Effects of pH on the Dispersion and Cell Performance of LiCoO2 Cathodes Based on the Aqueous Process, ”

J. Mater. Sci., 42, 5773-5777, 2006. (SCI)

 

Chia-Chen Li*, Jyh-Tsung Lee, Chen-Yu Lo, Mao-Sung Wu,

“ Effects of PAA-NH4 Addition on the Dispersion Property of Aqueous LiCoO2 Slurries and the Cell Performance of As-Prepared LiCoO2 Cathodes, ”

Electrochem. Solid-State Lett., 8, A509-A512, 2005. (SCI)

 

Chia-Chen Li, Jau-Ho Jean*,

“ Effects of Ethylene Glycol, Thickness, and B2O3 on PVA Distribution in Dried BaTiO3 Green Tape, ”

Mater. Chem. Phys., 94, 78-86, 2005. (SCI)

 

Chia-Chen Li*, Mei-Whei Chang,

“ Colloidal Stability of CuO Nanoparticles in Alkanes via Oleate Modifications, ”

Mater. Lett., 58, 3903-07, 2004. (SCI)

 

Chia-Chen Li, Jau-Ho Jean*,

“ Dissolution and Dispersion Behavior of Barium Carbonate in Aqueous Suspensions, ”

J. Am. Ceram. Soc., 85, 2977-83, 2002. (SCI)

 

Chia-Chen Li and Jau-Ho Jean*,

“ Interaction Between Dissolved Ba2+ and PAA-NH4 Dispersant in Aqueous BaTiO3 Suspensions, ”

J. Am. Ceram. Soc., 85, 1449-55, 2002. (SCI)

 

Chia-Chen Li, Jau-Ho Jean*,

“ Interactions of Organic Additives with Boric Oxide in Aqueous Barium Titanate Suspensions, ”

J. Am. Ceram. Soc., 85, 1441-48, 2002. (SCI)

 

 

李嘉甄 Chia-Chen Li Professor     Contact information   Office : R426, Delta Building (台達館426室) E-mail : cc.li@mx.nthu.edu.tw Phone : 03-5715131 #35364
Research interests   -- Dispersion science -- Energy-storage materials for Li-ion battery -- Self-healing Microcapsules -- Porous materials

 

 

 

 

 

 

Porous Microspheres

 

 

A new type of designed copolymers has been synthesized for the formation of porous polymeric microspheres. The copolymers contain hydrophobic (styrene, methyl methacrylate, vinylbenzyl chloride, or vinylbenzyl ethyl ether) and hydrophilic (vinylbenzyl alcohol) repeating units. Since the specially designed copolymers have unique chemical and physical properties, the porous structure can be easily accomplished by a facile single-step process. The resulting porous microspheres exhibit good morphological quality, showing open pore structure with a pore size ranging from submicrometer to micrometer, by neither use of porogens nor the requirement of complicated multistep emulsifications. The discovery for the exceptional performance of pores in microspheres is exciting and groundbreaking. The chemical features of the proposed copolymers for the availability in the formation of porous architecture provide important insights into the design principle of high quality porous structures.

 

The zirconia crucible containing the black powder carbonized from the swelled PSV porous microspheres. Raman spectrum of porous carbon spheres prepared from swelled PSV microspheres (compared with commercial carbon black).

 

Compared to conventional dense materials, porous materials exhibit special features such as relatively low density, high surface area, light weight, sound and thermal insulation, and good permeating selectivity. These remarkable properties have made porous materials of great scientific and technological interest, enabling their use in a wide range of industrial applications and products, including efficient adsorbents for storage and controlled release, carriers for medicines and biomaterials, supports for conversion reactions, supercapacitors, batteries, solar power, and fuel cells. With an increased demand for new materials in surface-related applications, research into developing fabrication techniques for porous materials has increased. Among material types and architectures, polymeric porous spheres have been the highest developed, and they are also common precursors and templates for other materials like carbons, metals, and ceramics in the fabrication of porous structures.

 

 

 

 

 

ref.　Chem. Mater., 28 [17], 6089–6095, 2016.

 

MicroCapsules

 

 

 

ref.　J. Mater. Chem. A, 5, 25583–25593, 2017.

 

Microcapsules have attracted attention in the field of novel and advanced materials due to their potential applications in hightech industries. The advantage of encapsulating specific materials in the core of a microcapsule is that the core materials can be quarantined to function only at the right time, i.e. they will remain stable inside the microcapsule until they are triggered. Due to wide variety of species available for the core materials, microcapsules have the potential to be employed in a wide industrial products, for instance, food and cosmetic additives, drug delivering carriers for bio-material and medicine fields, self-healing additives for microstructural and functional restorations and so on. Among these applications, the self-healing function of microcapsules has attracted the most interest in recent decades. The research team of Scott R. White et al. was the first to reveal the potential for utilizing microcapsules as self-healing materials. From their report in 2001, they successfully embedded the microcapsules of poly(urea–formaldehyde) (PUF) in resin which was cast on the surface of a certain substrate that needs to be protected or be able to restore itself as needed. Based on the healing mechanism, not only the structural fracture but other physical properties such as anti-corrosion or electrical conductivity can also be spontaneously restored.

 

 

 

Cross-sectional SEMimage of a broken microcapsule embeddedin resin, shell thickness about 50-100 nm	SEM images of (a)microcapsules (b)microcapsules with Ag coated (c)Aqueous suspensions of microcapsules (left) and Ag-coated microcapsules.

 

 

Since the shell of most microcapsules is primarily polymeric which is mechanically soft and less compatible with lots of inorganic materials, the utilization of microcapsules is generally circuitous; the microcapsules are embedded in a polymeric film on the top of the target substrate that needs the self-healing function. This is especially true when the substrate is a metal- or ceramic-based material because of the very different surface tensions. This procedure makes the use of microcapsules complicated and limits their use in other applications. On the other hand, the triggering force may decay during transmission and only the microcapsules near the interface between the polymer and the target substrate have the opportunity to function, while those embedded far from the interface will become useless. To make the use of microcapsules more convenient and more efficient in the healing process, wastage of microcapsules should be reduced and they should be buried directly in the target substrate.

 

 

(a) Variation in current before and after being damaged for three circuits with and without embedded 20vol% of PUF-C20 and Ag@mPUF-C20 microcapsules under a consstant applied voltage of 1 V. Schematic mechanism for restoration: (b1) direct embedding of microcapsules (green) in the Ag-based circuit matrix (gray) on a glass substrate (light blue); (b2) healing material in the core after damaged; (b3) melted healing material released; (b4) damaged recovered from both fillings of the Ag particles rearranged from the matrix and the re-solidified healing material. (c) Cross-sectional SEM image of recovered zone near the interface between the Ag matrix and glass for the microcapsules embedded circuit.

 

 

(a)Diagram of cracks may not be completely recovered when microcapsules are poorly distributed. (b) This diagram shows the high probability for cracks being restored when microcapsules are well-dispersed.

 

 

 

ref.　 RSC Adv., 5, 104145-104148, 2015.

 

 

Li-ion Batteries

 

ref. ChemElectroChem, DOI: 10.1002/celc.201801594.

ref.　ChemElectroChem, DOI: 10.1002/celc.201801251.

 

Ever since lithium iron phosphate (LiFePO4) was reported as a potential cathode-active material for a lithium-ion battery by Goodenough and his coworkers in 1997, it has attracted widespread attention and been extensively studied during the past decade. The advantages of the olivine-structured LiFePO4 include a large theoretical capacity, good lifecycle performance, and safety. The excellent structural stability of LiFePO4, which results from strong Fe-P-O bonds, also greatly increases its thermal stability at high temperatures in its fully charged state. In addition, the low cost and toxicity of LiFePO4 owing to its environmentally compatible constituents make it a promising cathode active material for large batteries.

 

 

Li-ion battery structure ref:　J. Mater. Chem. A, 2015, 3, 2454-2484

 

hybrid circuit co-fired ceramics ref:wiki	nano-LiFePO4

 

 

LiFePO4 has some disadvantages, such as poor electrical conductivity (~10-9 cm-1) and the diffusion of lithium ions (Li+) in LiFePO4. These issues result in losses in capacity and rate capability and thus hinder the commercial application of LiFePO4. The use of fine LiFePO4 particles has been proposed to improve Li+ diffusion. Furthermore, surface coating with a conductive material is a commonly used approach to enhance the electrical conductivity of LiFePO4. Among the various possible conductive coating materials, carbon is the most prevalent because of its high chemical stability. Commercially produced LiFePO4 powders are available with a varying amount of carbon content that typically ranges from 1 to 5 wt% because of the differences in techniques used for the synthesis of LiFePO4. For the fabrication of electrodes, electrode materials are typically mixed using either a water-based (aqueous) or solvent-based (non-aqueous) process. The aqueous process is gaining favor and has attracted significant interest because of its environmental consistency and cost considerations. However, the aqueous process has a drawback, i.e., the agglomeration of most oxides, including LiFePO4; until now, the only efficient approach to prevent powder agglomeration has been the addition of an appropriate dispersant to the system. Furthermore, several reports have noted that not all commercial LiFePO4 powders exhibit the same dispersity in aqueous slurries, i.e., notable differences in the dispersion properties of the aqueous slurries prepared with powders from different production lots made by the same supplier may be observed. This variety in the dispersity of LiFePO4 powder in water is an important issue that has caused great concern in LiFePO4-related industries. In addition, the indeterminate dispersity of the powders may cause end users to manipulate them imprecisely resulting in unsuitable electrode slurries. Typical commercially available LiFePO4 powders are obtainable as both dispersions and gels in water. Dispersible LiFePO4 (D-LFP) and gelled LiFePO4 (G-LFP) are two such LiFePO4 powders with the same physicochemical properties of crystallinity, a median particle size (d50) of 2.2 mm, and an approximate carbon content of 1.07-1.20 wt%; these powders were acquired from the same supplier. When we processed them in water by adding the same ingredients, different distinctive flow behaviors of the as-prepared aqueous slurries were observed. The aqueous slurry prepared from the D-LFP powder shows fluidity, whereas the slurry from G-LFP resembled a jelly-like gel. As the formation of powder gel will be detrimental to the electrode-manufacturing process, especially for the slurry-sieving and slurry-casting steps, understanding the cause for the deviation in the dispersity of powders is essential and a prerequisite.

 

Schemes for (a)H-bondings between carbon-coated G-LFP particles and (b) gelation mechanism of G-LFP due to the bridging of SCMC.

 

 

 

 

ref.　 J. Power Sources, 310, 45-53, 2016.

 

 

Dispersion

 

 

 

ref. J. Colloid Interface Sci., 520, 119-126, 2018.

 

Titania (TiO2) is an important and widely used material in industries ranging from traditional to highly technical because of its attractive and extensive physicochemical properties. TiO2 must be compatible with other materials for it to distribute homogeneously in composites and for it to be useful in various applications. Therefore, the dispersity of TiO2, which is determined by its surface properties, is an important issue that was examined in past decades. Commercial TiO2 nanopowders usually exhibit a variety of surface properties. For instance, they show acid–base properties that vary with the manufacturer and production process. Different manufacturers or manufacturing processes may use a variety of dopants for TiO2 to modify or improve its physicochemical properties, such as thermal stability and chemical activity. As a result, the surface chemistries of commercial TiO2 are frequently unclear, making it difficult to control its dispersion.

 

 

ref.　 J. Am. Ceram. Soc. in press, 2016.

 

 

Nano materials

 

nano-diamond	nano-diamond suspension	nano-diamond suspension (after being dispersed)
BaTiO3@SiO2 core-shell	nano-BaTiO3 (after being dispersed)	nano-silver
nano-silver (after dispersion)

 

 

 

 

Composite Materials

 

 

 

 

 

 

 

 

 

 

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