{"id":10,"date":"2020-04-08T02:43:32","date_gmt":"2020-04-08T02:43:32","guid":{"rendered":"http:\/\/graphene.nus.edu.sg\/nus2dmicrosite\/?page_id=10"},"modified":"2026-04-13T12:54:48","modified_gmt":"2026-04-13T04:54:48","slug":"publications","status":"publish","type":"page","link":"https:\/\/graphene.nus.edu.sg\/barbaros\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"

GOOGLE SCHOLAR<\/a><\/h3>\n

2026<\/h4>\n
    \n
  1. 3D interconnected pore networks enable superior volumetric CO2<\/sub> uptake in amine-functionalized nanoporous carbon for direct air capture
    \n<\/a><\/strong>Zekai Ji, Sanjeevi Jayakumar, Carlos Maria Alava Limpo, Aravind Madhav, Maxim Trubyanov, Pengxiang Zhang, Daria V. Andreeva, Jong Hak Lee, Barbaros \u00d6zyilmaz
    \nCarbon Capture Science & Technology <\/strong><\/em>(March 2026)<\/span><\/li>\n
  2. Breaking the 2-nm Barrier in Hard Disk Drives Using Monolayer Amorphous Carbon Overcoats
    \n<\/a><\/strong>Hongji Zhang, Artem K. Grebenko, Dmitrii Litvinov, Wenwen Zheng, Konstantin V. Iakoubovskii, Sergey Y. Grebenchuk, Anna Makarova, Alexander Fedorov, Andrei Starkov, Carlo M. Orofeo, Denis V. Vyalikh, Mario Lanza, Maciej Koperski, Kostya S. Novoselov, Chee-Tat Toh & Barbaros \u00d6zyilmaz
    \nAdvanced Materials<\/strong><\/em> (February 2026)<\/span><\/li>\n<\/ol>\n

    <\/h4>\n

    2025<\/h4>\n
      \n
    1. Electric field-tunable ferromagnetism in a van der Waals semiconductor up to room temperature;
      \n<\/a><\/strong>Deyi Fu, Jiawei Liu, Fuchen Hou, Xiao Chang, Tingyu Qu, Johan F\u00e9lisaz, Gunasheel Kauwtilyaa Krishnaswamy, Sergey Grebenchuk, Yuang Jie, Kenji Watanabe, Takashi Taniguchi, Vitor M. Pereira, Kostya S. Novoselov, Maciej Koperski, Nikolai L. Yakovlev, Anjan Soumyanarayanan, Ahmet Avsar, Oleg V. Yazyev, Junhao Lin & Barbaros \u00d6zyilmaz
      \nNature Communications<\/strong><\/em> (November 2025)<\/span><\/li>\n
    2. Monolayer Amorphous Carbon: Unlocking Disorder-Induced Lithiophilicity;
      \n<\/a><\/strong>Lu Shi, Hanning Zhang, Artem K. Grebenko, Ruslan Yamaletdinov, Rejaul SK, Ranjith Shivajirao, Zheng Jue Tong, Sergey Luchkin, Hongji Zhang, Konstantin V. Iakoubovskii, Alena A. Alekseeva, Andrei Starkov, Carlo M. Orofeo, Junhao Lin, Kazutomo Suenaga, Chee-Tat Toh, Remi Mahfouz, Talah M. Tayeb, Nada Qari, Stefan Adams, Bent Weber, Oleg V. Yazyev, Barbaros \u00d6zyilmaz
      \nAdvanced Science<\/strong><\/em> (November 2025)<\/span><\/li>\n
    3. Dry Transfer of CVD Graphene Film Using Adhesion Switchable Ferroelectric Polymers;
      \n<\/a><\/strong>Deqiang Zhang, Jing Ying Yeo, Hanning Zhang, Ruslan Yamaletdinov, Qian Yang, Yufeng Zhan, I\u00f1igo Martin-Fernandez, Oleg V. Yazyev, Chee-Tat Toh, Barbaros \u00d6zyilmaz
      \nAdvanced Materials<\/strong><\/em> (November 2025)<\/span><\/li>\n
    4. Robust Silicon-Based Anode with High Energy Density upon Dual Welding Encapsulation;
      \n<\/a><\/strong>Wenhui Lai, Jong Hak Lee, Zhen Yuan Yeo, Yue Yuan, Yuqing Liu, Lu Shi, Yanhui Pu, Yong Kang Ong, Carlos Maria Alava Limpo, Yifan Rao, Ting Xiong, Mario Lanza, N. Duane Loh, Barbaros \u00d6zyilmaz
      \nACS Nano<\/strong><\/em> (October 2025)<\/span><\/li>\n
    5. Reinforcement-free monolithic all-in-one structural supercapacitors; <\/a>
      \n<\/strong>Yifan Rao, Jong Hak Lee, Yanhui Pu, Yong Kang Ong, Lu Shi, Wenhui Lai, Carlos Limpo, Yue Yuan, Ting Xiong, Mario Lanza, \u00a0Barbaros \u00d6zyilmaz
      \nChemical Engineering Journal<\/strong><\/em> (August 2025)<\/span><\/li>\n
    6. Adjustable SiC interfacial layers toward reliable Si-based anode applications; <\/a>
      \n<\/strong>Wenhui Lai, Jong Hak Lee, Yue Yuan, Yong Kang Ong, Carlos Limpo, Lu Shi, Yanhui Pu, Yifan Rao, Mario Lanza, \u00a0Barbaros \u00d6zyilmaz
      \nNanoscale Horizons<\/strong><\/em> (August 2025)<\/span><\/li>\n
    7. Superior Adhesion of Monolayer Amorphous Carbon to Copper;<\/a>
      \n<\/strong>Hongji Zhang, Artem K. Grebenko, Konstantin V. Iakoubovskii, Hanning Zhang, Ruslan Yamaletdinov, Anna Makarova, Alexander Fedorov, Rejaul SK, Ranjith Shivajirao, Zheng Jue Tong, Sergey Grebenchuk, Ugur Karadeniz, Lu Shi, Denis V. Vyalikh, Ya He, Andrei Starkov, Alena A. Alekseeva, Chuan Chu Tee, Carlo Mendoza Orofeo, Junhao Lin, Kazutomo Suenaga, Michel Bosman, Maciej Koperski, Bent Weber, Kostya S. Novoselov, Oleg V. Yazyev, Chee-Tat Toh, Barbaros \u00d6zyilmaz
      \nAdvanced Materials<\/strong><\/em> (May 2025)<\/span><\/li>\n
    8. Intrinsic toughening in monolayer amorphous carbon nanocomposites;<\/a>
      \n<\/strong>Bongki Shin, Bo Ni, Chee-Tat Toh, Doug Steinbach, Zhenze Yang, Lucas M. Sassi, Qing Ai, Kangdi Niu, Junhao Lin, Kazu Suenaga, Yimo Han, Markus J. Buehler, Barbaros \u00d6zyilmaz, Jun Lou
      \nMatter<\/strong><\/em> (January 2025)<\/span><\/li>\n<\/ol>\n

       <\/p>\n

      2024<\/strong><\/h4>\n
        \n
      1. Engineering a Hierarchy of Disorder: A New Route to Synthesize High-Performance 3D Nanoporous All-Carbon Materials;<\/a>
        \n<\/strong>Jong Hak Lee, N. Duane Loh, Zhen Yuan Yeo, Yong Kang Ong, Deepan Balakrishnan, Carlos Maria Alava Limpo, Abhik Datta, Cagdas Cetin, Shoucong Ning, Clarissa Wong, Jian Shi, Fuchen Hou, Junhao Lin, Tadahiro Minamikawa, Tomonori Ito, Hiroyuki Kamisuki, Stephen Pennycook, Paul Matsudaira, Barbaros \u00d6zyilmaz
        \nAdvanced Materials<\/strong><\/em> (April 2024)<\/span><\/li>\n
      2. Upconversion electroluminescence in 2D semiconductors integrated with plasmonic tunnel junctions<\/a>;<\/a>
        \n<\/strong>Zhe Wang, Vijith Kalathingal, Maxim Trushin, Jiawei Liu, Junyong Wang, Yongxin Guo, Barbaros \u00d6zyilmaz, Christian A Nijhuis, Goki Eda
        \nNature Nanotechnology<\/strong><\/em> (April 2024)<\/span><\/li>\n
      3. High mechanical strength Si anode synthesis with interlayer bonded expanded graphite structure for lithium-ion batteries;<\/a><\/strong>
        \nWenhui Lai, Jong Hak Lee, Lu Shi, Yuqing Liu, Yanhui Pu, Yong Kang Ong, Carlos Limpo, Ting Xiong, Yifan Rao, Chorng Haur Sow, Barbaros \u00d6zyilmaz<\/span>
        \nJournal of Energy Chemistry<\/strong><\/em> (Feb 2024)<\/span><\/li>\n
      4. Observation of weak localization in dual-gated bilayer\u00a0<\/span><\/a>MoS2;
        \n<\/a><\/strong>Tingyu Qu, Michele Masseroni, Takashi Taniguchi, Kenji Watanabe, Barbaros \u00d6zyilmaz, Thomas Ihn, Klaus Ensslin
        \n<\/span>Physical Review Research<\/strong><\/em> (Feb 2024)<\/span><\/li>\n
      5. Highly anisotropic spin transport in ultrathin black phosphorus;
        \n<\/a><\/strong>Luke Cording, Jiawei Liu, Jun You Tan, Kenji Watanabe, Takashi Taniguchi, Ahmet Avsar, Barbaros \u00d6zyilmaz
        \n<\/span>Nature Materials<\/strong><\/em> (Feb 2024)<\/span><\/li>\n
      6. Interfacial design towards stable zinc metal-free zinc-ion batteries with high energy density<\/a>;
        \n<\/a><\/strong>Ting Xiong, Deqiang Zhang, Jing Ying Yeo, Yufeng Zhan, Yong Kang Ong, Carlos Maria Alava Limpo, Lu Shi, Yifan Rao, Yanhui Pu, Wenhui Lai, Jonghak Lee, Wee Siang Vincent Lee, Barbaros \u00d6zyilmaz
        \n<\/span>Journal of Materials Chemistry A<\/strong><\/em> (Jan 2024)<\/li>\n<\/ol>\n

         <\/p>\n

        2023<\/strong><\/h4>\n
          \n
        1. Method of protecting a magnetic layer of a magnetic recording medium<\/a>;<\/a><\/strong>\n
          \n
          Barbaros Oezyilmaz, Andreas Volker Stier, Chee Tat Toh, Antonio Helio Castro Neto<\/div>\n
          US Patent App. 15\/223,915 (Dec 2023)<\/div>\n<\/div>\n<\/li>\n
        2. A seed layer, a heterostructure comprising the seed layer and a method of forming a layer of material using the seed layer<\/a>;<\/a><\/strong>
          \nBarbaros Oezyilmaz, Chee Tat Toh, Irfan Haider Abidi<\/span>
          \nUS Patent App. 17\/910,180 \u00a0(May 2023)<\/span><\/li>\n<\/ol>\n

          <\/h4>\n

          2022<\/strong><\/h4>\n
            \n
          1. Electrode, electrochemical cell and methods of forming the same;<\/a><\/strong>
            \nBarbaros Oezyilmaz, Cagdas Cetin, Chee Tat Toh, Irfan Haider Abidi, Pieremanuele Canepa, Xiao Feng Lim<\/span>
            \nUS Patent App. 17\/764,612 \u00a0(March 2022)<\/span><\/li>\n
          2. Electronic device including one or more monolayer amorphous films and method of forming the same;<\/a><\/strong>
            \nBarbaros Oezyilmaz, Chee Tat Toh, Irfan Haider Abidi<\/span>
            \nUS Patent App. 17\/640,669 (August 2022)<\/span><\/li>\n
          3. Monolithic and fractal carbon foams and methods of preparing and using same;<\/a><\/strong>
            \nBarbaros Oezyilmaz, Jonghak Lee, Clarissa Chui Ling Wong, Cagdas Cetin, Xiao Feng Lim, Yong Kang Ong<\/span>
            \nUS Patent App. 17\/535,246 \u00a0(March 2022)<\/span><\/li>\n<\/ol>\n

            <\/h4>\n

            2021<\/strong><\/h4>\n
              \n
            1. Proton conductive two-dimensional amorphous carbon film for gas membrane and fuel cell applications;<\/a><\/strong>
              \nBarbaros Ozyilmaz, Henrik Andersen, Chee Tat Toh<\/span>
              \nUS Patent 11\/114,674 (September 2021)<\/span><\/li>\n
            2. Two dimensional amorphous carbon as overcoat for heat assisted magnetic recording media;<\/a><\/strong>
              \nBarbaros Ozyilmaz, TOH Chee-Tat, Hongji Zhang, Alexander Mayorov, Darim Badur Ferry, Henrik Andersen, Cagdas Cetin, Irfan Haider Abidi<\/span>
              \nUS Patent 10\/984,830 (April 2021)<\/span>              <\/a><\/strong><\/li>\n
            3. Two-dimensional amorphous carbon coating and methods of growing and differentiating stem cells;<\/a><\/strong>
              \nBarbaros Ozyilmaz, Carlo Mendoza Orofeo, Henrik Andersen, Hongji Zhang, Chee Tat Toh, Inigo Martin-fernandez<\/span>
              \nUS Patent 11\/192,788<\/span> (January<\/span> 2021)<\/li>\n<\/ol>\n

              <\/h4>\n

              2020<\/strong><\/a><\/strong><\/h4>\n
                \n
              1. Ordered growth of large crystal graphene by laser-based localized heating for high throughput production;<\/a><\/strong>
                \nBarbaros \u00d6zyilmaz, Chee Tat Toh<\/span>
                \nUS Patent 10\/815,584<\/span>\u00a0(October 2022)<\/li>\n
              2. Heteromoir\u00e9 Engineering on Magnetic Bloch Transport in Twisted Graphene Superlattices;<\/a><\/strong>
                \nFR Lin, JB Qiao, JY Huang, JW Liu, DY Fu, AS Mayorov, H Chen, P Mukherjee, TY Qu, CH Sow, K Watanabe, T Taniguchi, B O\u0308zyilmaz
                \nNano Letters<\/strong><\/em> (September 2020)<\/li>\n
              3. Colloquium: Spintronics in graphene and other two-dimensional materials;<\/a><\/strong>
                \nA Avsar, H Ochoa, F Guinea, B Ozyilmaz, BJ van Wees, IJ Vera-Marun<\/span>
                \nReviews of Modern Physics<\/strong><\/em> (June 2020)<\/span><\/li>\n
              4. Method of pulsed laser-based large area graphene synthesis on metallic and crystalline substrates;<\/a><\/strong>
                \nBarbaros Ozyilmaz, Andreas Volker Stier, Chee Tat Toh, Antonio Helio Castro Neto<\/span>
                \nUS Patent App. 10\/683,586\u00a0 (June 2020)<\/span><\/li>\n
              5. Stabilization of antiferromagnetism in 1T-Fe0.05TaS2;<\/a><\/strong>
                \nQ Niu, W Zhang, YT Chan, ECT O\u2019Farrell, R Doganov, KY Yip, Kwing To Lai, WC Yu, B \u00d6zyilmaz, GR Stewart, JS Kim, Swee K Goh<\/span>
                \nPhysical Review Research<\/strong><\/em> (June 2020)<\/span><\/li>\n
              6. Proton and Li-Ion Permeation through Graphene with Eight-Atom-Ring Defects;<\/a><\/strong>
                \nEoin Griffin, Lucas Mogg, Guang-Ping Hao, Gopinadhan Kalon, Cihan Bacaksiz, Guillermo Lopez-Polin, TY Zhou, Victor Guarochico, Junhao Cai, Christof Neumann, Andreas Winter, Michael Mohn, Jong Hak Lee, Junhao Lin, Ute Kaiser, Irina V Grigorieva, Kazu Suenaga, Barbaros Ozyilmaz, Hui-Min Cheng, Wencai Ren, Andrey Turchanin, Francois M Peeters, Andre K Geim, Marcelo Lozada-Hidalgo<\/span>
                \nACS Nano<\/strong><\/em> (May 2020)<\/span><\/li>\n
              7. Electrochromic device with graphene\/ferroelectric electrode;<\/a><\/strong>
                \nBarbaros \u00d6zyilmaz, Eeshan Sandeep Kulkarni, I\u00f1igo Martin Fernandez, Chee Tat Toh, Antonio Helio Castro Neto<\/span>
                \nUS Patent App. 10\/663,833\u00a0 (May 2020)<\/span><\/li>\n
              8. Gate controlled valley polarizer in bilayer graphene;<\/a><\/strong>
                \nHao Chen, Pinjia Zhou, Jiawei Liu, Jiabin Qiao, Barbaros Oezyilmaz, Jens Martin<\/span>
                \nNature communications<\/strong><\/em> (Mar 2020)<\/span><\/li>\n
              9. Synthesis and properties of free-standing monolayer amorphous carbon;<\/a><\/strong>
                \nChee-Tat Toh, Hongji Zhang, Junhao Lin, Alexander S. Mayorov, Yun-Peng Wang, Carlo M. Orofeo, Darim Badur Ferry, Henrik Andersen, Nurbek Kakenov, Zenglong Guo, Irfan Haider Abidi, Hunter Sims, Kazu Suenaga, Sokrates T. Pantelides &\u00a0Barbaros \u00d6zyilmaz\u00a0<\/span>
                \nNature<\/strong><\/em> (Jan 2020)<\/span><\/li>\n<\/ol>\n

                <\/h4>\n

                2019<\/strong><\/h4>\n
                  \n
                1. Method for controlling differentiation of stem cells using graphene substrates;<\/a><\/strong>
                  \nBarbaros Oezyilmaz, Giorgia Pastorin, Henrik Andersen\u00a0<\/span>
                  \nUS Patent App. 10\/316,290\u00a0 (June 2019)<\/span><\/li>\n
                2. Selective Defect Formation in Hexagonal Boron Nitride;<\/a><\/strong>
                  \nIrfan H Abidi, Noah Mendelson, Toan Trong Tran, Abhishek Tyagi, Minghao Zhuang, Lu\u2010Tao Weng, Barbaros \u00d6zyilmaz, Igor Aharonovich, Milos Toth, Zhengtang Luo<\/span>
                  \nAdvanced Optical Materials<\/strong><\/em> (May 2019)<\/span><\/li>\n
                3. Two dimensional amorphous carbon as overcoat for heat assisted magnetic recording media;<\/a><\/strong>
                  \nBarbaros Ozyilmaz, TOH Chee-Tat, Hongji Zhang, Alexander Mayorov, Darim Badur Ferry, Henrik Andersen, Cagdas Cetin, Irfan Haider Abidi<\/span>
                  \nUS Patent App. 16\/181,656\u00a0 (March 2019)<\/span><\/li>\n
                4. Investigation of h-BN\/Graphene Spin Valve;<\/a><\/strong>
                  \nTingyu Qu; Junye Huang; Deyi Fu; Jiawei Liu; Barbaros Ozyilmaz\u00a0<\/span>
                  \nAPS 2019, G70. 190 (March 2019)<\/span><\/li>\n
                5. Spin transport properties in ultra-thin black phosphorus;<\/a><\/strong>
                  \nJiawei Liu; Deyi Fu; Barbaros Oezyilmaz<\/span>
                  \nAPS 2019, G70. 191 (March 2019)<\/span><\/li>\n
                6. Human-machine interface with graphene-pyroelectric materials;<\/a><\/strong>
                  \nBarbaros \u00d6zyilmaz, Eeshan Sandeep Kulkarni, Sascha Pierre Heussler, Antonio Helio Castro Neto, Henrik Andersen<\/span>
                  \nUS Patent App. 10\/228,784\u00a0 (March 2019)<\/span><\/li>\n<\/ol>\n

                  <\/h4>\n

                  2018<\/strong><\/h4>\n
                    \n
                  1. Proton conductive two-dimensional amorphous carbon film for gas membrane and fuel cell applications<\/a>;<\/strong>
                    \nBarbaros Ozyilmaz, Carlo Mendoza Orofeo, Henrik Andersen, Hongji Zhang, Chee Tat Toh, Inigo Martin-fernandez<\/span>
                    \nUS Patent App. 16\/049,03 (Nov 2018)<\/span><\/li>\n
                  2. Two-dimensional amorphous carbon coating and methods of growing and differentiating stem cells;<\/a><\/strong>
                    \nBarbaros Ozyilmaz, Carlo Mendoza Orofeo, Henrik Andersen, Hongji Zhang, Chee Tat Toh, Inigo Martin-fernandez<\/span>
                    \nUS Patent App. 15\/901,099 (Aug 2018)<\/span><\/li>\n
                  3. Hot press induced formation of an ordered graphene and few layered graphene sheets<\/a>;<\/strong>
                    \nJonghak Lee, Barbaros \u00d6zyilmaz<\/span>
                    \nUS Patent 9,969,618 (May 2018)<\/span><\/li>\n
                  4. Synthesis of three-dimensional graphene foam: use as supercapacitors;<\/a><\/strong>
                    \nBarbaros Ozyilmaz, Orhan Kahya, Jonghak Lee<\/span>
                    \nUS Patent 9,929,287 (March 2018)<\/span><\/li>\n<\/ol>\n

                    <\/h4>\n

                    2017<\/strong><\/h4>\n
                      \n
                    1. Optospintronics in graphene via proximity coupling;<\/a><\/strong>
                      \nAvsar, A., Unuchek, D., Liu, J., Sanchez, O.L., Watanabe, K., Taniguchi, T,.\u00a0\u00d6zyilmaz, B., and Kis, A.<\/span>
                      \nACS Nano<\/strong><\/em> (Oct 2017)<\/span><\/li>\n
                    2. Van der Waals bonded Co\/h-BN contacts\u00a0to ultra-thin Black Phosphorus devices;<\/a><\/strong>
                      \nAhmet Avsar, Jun You Tan, Xin Luo, Khoong Hong Khoo, Yuting Yeo, Kenji Watanabe, Takashi Taniguchi, Su Ying Quek, and\u00a0<\/span>\u00d6<\/span>zyilmaz Barbaros<\/span>
                      \nNano Letters<\/strong><\/em> (Aug 2017)<\/span><\/li>\n
                    3. Gate-tunable black phosphorus spin valve with nanosecond spin lifetimes;<\/a><\/strong>
                      \nAvsar, A., Tan, J.Y., Kurpas, M., Gmitra, M., Watanabe, K., Taniguchi, T., Fabian, J., and \u00d6zyilmaz, B.<\/span>
                      \nNature Physics<\/strong><\/em> (May 2017)<\/span><\/li>\n
                    4. Pyroelectric detector using graphene electrode;<\/a><\/strong>
                      \nBarbaros Ozyilmaz, Eeshan Sandeep Kulkarni, Sascha Pierre Heussler, Antonio Helio Castro Neto<\/span>
                      \nUS Patent 9,797,779 (Oct 2017)<\/span><\/li>\n
                    5. Highly dense nano-carbon foam with controlled porosity synthesized from hollow carbon nanoparticles;<\/a><\/strong>
                      \nArunabha Ghosh, Jonghak Lee, Srinivasan Natarajan, Barbaros Oezyilmaz, Antonio Helio Castro Neto<\/span>
                      \nUS Patent 9,725,322 (Aug 2017)<\/span><\/li>\n
                    6. Touch screen devices employing graphene networks with polyvinylidene fluoride films;<\/a><\/strong>
                      \nBarbaros Ozyilmaz<\/span>
                      \nUS Patent 9,715,247 (Jul 2017)<\/span><\/li>\n
                    7. Graphene as a protective overcoat for magnetic media without the use of a nucleation layer<\/a>;<\/strong>
                      \nWah Lawrence Ng, Andreas Volker Stier, I\u00f1igo Martin Fernandez, Barbaros \u00d6zyilmaz, Antonio Helio Castro Neto<\/span>
                      \nUS Patent App. 15\/301,790 (Jul 2017)<\/span><\/li>\n
                    8. Human-machine interface with graphene-pyroelectric materials<\/a>;<\/strong>
                      \nBarbaros \u00d6zyilmaz, Eeshan Sandeep Kulkarni, Sascha Pierre Heussler, Antonio Helio Castro Neto, Henrik Andersen<\/span>
                      \nUS Patent App. 15\/323,243 (May 2017)<\/span><\/li>\n
                    9. Method of protecting a magnetic layer of a magnetic recording medium<\/a>;<\/strong>
                      \nBarbaros Oezyilmaz, Andreas Volker Stier, Chee Tat Toh, Antonio Helio Castro Neto<\/span>
                      \nUS Patent App. 15\/223,915 (Feb 2017)<\/span><\/li>\n<\/ol>\n

                      <\/h4>\n

                      2016<\/strong><\/h4>\n
                        \n
                      1. Rashba Interaction and Local Magnetic Moments in a Graphene-BN Heterostructure Intercalated with Au;<\/a><\/strong>
                        \nO\u2019Farrell, E. C. T., Tan, J. Y., Yeo, Y., Koon, G. K. W., \u00d6zyilmaz, B., Watanabe, K. and Taniguchi, T.
                        \nPhysical Review Letters<\/strong><\/em>\u00a0117, 076603 (Aug 2016)
                        \n                        arXiv link<\/a><\/span><\/li>\n
                      2. Enhanced Photoresponse from Phosphorene\u2013Phosphorene-Suboxide Junction Fashioned by Focused Laser Micromachining;<\/a><\/strong>
                        \nLu, J., Carvalho, A., Jing, W., Liu, H., Tok, E. S., Castro Neto, A. H., \u00d6zyilmaz, B., and Sow, C. H.
                        \nAdvanced Materials<\/strong><\/em> 28 (21), 4090\u20134096 (Jun 2016)<\/span><\/li>\n
                      3. Ultrafast optical switching of infrared plasmon polaritons in high-mobility graphene;<\/a><\/strong>
                        \nNi, G.-X., Wang, L., Goldflam, M. D., Wagner, M., Fei, Z., McLeod, A. S., Liu, M. K., Keilman, F., \u00d6zyilmaz, B., Castro Neto, A. H., Hone, J., Fogler, M. M., and Basov, D. N.
                        \nNature Photonics<\/strong><\/em> 10, 244\u2013247 (Apr 2016)<\/span><\/li>\n
                      4. Electron Doping of Ultrathin Black Phosphorus with Cu Adatoms;<\/a><\/strong>
                        \nKoenig, S. P., Doganov, R. A., Seixas, L., Carvalho, A., Tan, J. Y., Watanabe, K., Taniguchi, T., Yakovlev, N., Castro Neto, A. H., and \u00d6zyilmaz, B.
                        \nNano Letters<\/strong><\/em> 16 (4), pp 2145\u20132151 (Mar 2016)<\/span><\/li>\n
                      5. Electronic Spin Transport in dual-gated bilayer graphene;<\/a>\u00a0<\/span>OPEN ARTICLE<\/strong>
                        \nAvsar, A. ,Vera-Marun, I. J., Tan, J. Y., Koon, G. K. W., Watanabe, K., Taniguchi, T., Adam, S., and \u00d6zyilmaz, B.
                        \nNature Asia Materials<\/strong><\/em> 8, e274 (Mar 2016)
                        \n                        arXiv link<\/a><\/span><\/li>\n
                      6. Controlling many-body states by the electric field effect in a two-dimensional material;<\/a><\/strong>
                        \nLi, L. J., O\u2019Farrell, E. C. T., Loh, K. P., Eda, G., \u00d6zyilmaz, B., and Castro Neto, A. H.
                        \nNature<\/strong><\/em> 529, 185\u2013189 (Jan 2016)<\/span><\/li>\n<\/ol>\n

                        <\/h4>\n

                        2015<\/strong><\/h4>\n
                          \n
                        1. Enhanced spin\u2013orbit coupling in dilute fluorinated graphene;<\/a><\/strong>
                          \nAvsar, A., Lee, J. H., Koon, G. K. W., and \u00d6zyilmaz, B.
                          \n2D Materials<\/strong><\/em>, 2 (4) 044009 (Nov 2015)<\/span><\/li>\n
                        2. Spontaneous and specific myogenic differentiation of human mesenchymal stem cells on polyethylene glycol-linked multi-walled carbon nanotube films for skeletal muscle engineering;<\/a><\/strong>
                          \nZhao, C., Andersen, H., \u00d6zyilmaz, B., Ramaprabhu, S., Pastorin, G., and Ho, H. K.,
                          \nNanoscale<\/strong><\/em>, 7 18239-18249 (Oct 2015)<\/span><\/li>\n
                        3. Bandgap Engineering of Phosphorene by Laser Oxidation toward Functional 2D Materials;<\/a><\/strong>
                          \nLu, J., Wu, J., Carvalho, A., Ziletti, A., Liu, H., Tan, J., Chen, Y., Neto, A. H. C., \u00d6zyilmaz, B., and Sow, C. H.
                          \nACS Nano<\/em><\/strong>, 9 (10) 10411-10421 (Sep 2015)<\/span><\/li>\n
                        4. Plasmons in graphene moir\u00e9 superlattices;<\/a><\/strong>
                          \nNi, G.-X., Wang, H., Wu, J. S., Fei, Z., Goldflam, M. D., Keilmann, F., \u00d6zyilmaz, B., Castro Neto, A. H., Xie, X. M., Fogler, M. M., and Basov, D. N.
                          \nNature Materials, 14 1217-1222 (Sep 2015)<\/span><\/li>\n
                        5. A wafer-scale graphene and ferroelectric multilayer for flexible and fast-switched modulation applications;<\/a><\/strong>
                          \nZhu, M., Wu, J., Du, Z., Tay, R. Y., Li, H., \u00d6zyilmaz, B., and Teo, E. H. T.
                          \nNanoscale, 7 14730-14737 (Aug 2015)<\/span><\/li>\n
                        6. Quantum Transport Detected by Strong Proximity Interaction at a Graphene\u2013WS2 van der Waals Interface;<\/a><\/strong>
                          \nO\u2019Farrell, E. C. T., Avsar, A., Tan, J. Y., Eda, G., and \u00d6zyilmaz, B.
                          \nNano Letters, 15 (9) 5682-5688 (Aug 2015)<\/span><\/li>\n
                        7. Colossal Ultraviolet Photoresponsivity of Few-Layer Black Phosphorus;<\/a><\/strong>
                          \nWu, J., Koon, G. K. W., Xiang, D., Han, C., Toh, C. T., Kulkarni, E. S., Verzhbitskiy, I., Carvalho, A., Rodin, A. S., Koenig, S. P., Eda, G., Chen, W., Castro Neto, A. H., and \u00d6zyilmaz, B.
                          \nACS Nano, 9 (8) 8070-8077 (Jul 2015)<\/span><\/li>\n
                        8. Tuning and Persistent Switching of Graphene Plasmons on a Ferroelectric Substrate;<\/a><\/strong>
                          \nGoldflam, M. D., Ni, G.-X., Post, K. W., Fei, Z., Yeo, Y., Tan, J. Y., Rodin, A. S., Chapler, B. C., \u00d6zyilmaz, B., Castro Neto, A. H., Fogler, M. M., and Basov, D. N.
                          \nNano Letters, 15 (8) 4859\u20134864 (Jun 2015)<\/span><\/li>\n
                        9. Creating a Stable Oxide at the Surface of Black Phosphorus;<\/a><\/strong>
                          \nEdmonds, M. T., Tadich, A., Carvalho, A., Ziletti, A., O\u2019Donnell, K. M., Koenig, S. P., Coker, D. F., \u00d6zyilmaz, B., Castro Neto, A. H., and Fuhrer, M. S.
                          \nACS Appl. Mater. Interfaces, 7 (27) 14557\u201314562 (Jun 2015)<\/span><\/li>\n
                        10. Transport properties of ultrathin black phosphorus on hexagonal boron nitride;<\/a><\/strong>
                          \nDoganov, R. A., Koenig, Yeo, Y., S. P., Watanabe, K., Taniguchi, T., and \u00d6zyilmaz, B.
                          \nApplied Phys. Lett. 106, 083505 (Jun 2015)<\/span><\/li>\n
                        11. Large Frequency Change with Thickness in Interlayer Breathing Mode\u2014Significant Interlayer Interactions in Few Layer Black Phosphorus;<\/a><\/strong>
                          \nLuo, X., Lu, X., Koon, G. K. W., Castro Neto, A. H., \u00d6zyilmaz, B., Xiong, Q., and Quek, S. Y.
                          \nNano Letters, 15 (6) 3931-3938 (May 2015)<\/span><\/li>\n
                        12. Anomalous Spectral Features of a Neutral Bilayer Graphene;<\/a><\/strong>
                          \nCheng, C.-M., Xie, L. F., Pachoud, A., Moser, H. O., Chen, W., Wee, A. T. S., Castro Neto, A. H., Tsuei, K.-D. and \u00d6zyilmaz, B.
                          \nScientific Reports, 5:10025 (Mar 2015)<\/span><\/li>\n
                        13. Polymer-Enriched 3D Graphene Foams for Biomedical Applications;<\/a><\/strong>
                          \nWang, J. K., Xiong, G. M., Zhu, M., \u00d6zyilmaz, B., Castro Neto, A. H., Tan, N. S., and Choong, C.
                          \nACS Applied Mat. & Inter., 7 (15) 8275-8283 (Mar 2015)<\/span><\/li>\n
                        14. Air-Stable Transport in Graphene-Contacted, Fully Encapsulated Ultrathin Black Phosphorus-Based Field-Effect Transistors;<\/a><\/strong>
                          \nAvsar, A., Vera-Marun, I. J., Tan, J. Y., Watanabe, K., Taniguchi, T., Castro Neto, A. H., and \u00d6zyilmaz, B.
                          \nACS Nano, 9 (4) 4138-4145 (Mar 2015)<\/span><\/li>\n
                        15. Surface transfer doping induced effective modulation on ambipolar characteristics of few-layer black phosphorus;<\/a><\/strong>
                          \nXiang, D., Han, C., Wu, J., Zhong, S., Liu, Y., Lin, J., Zhang, X-A., Hu, W. P., \u00d6zyilmaz, B., Castro Neto, A. H., Wee, A. T. S., and Chen, W.
                          \nNature Comms., 6:6485 (Mar 2015)<\/span><\/li>\n
                        16. Transport properties of pristine few-layer black phosphorus by van der Waals passivation in inert atmosphere;<\/a><\/strong>
                          \nDoganov, R. A., O\u2019Farrell, E. C. T., Koenig, S. P., Yeo, Y., Ziletti, A., Carvalho, A., Campbell, D. K., Coker, D. F., Watanabe, K., Taniguchi, T., Castro Neto, A. H., and \u00d6zyilmaz, B.
                          \nNature Comms., 6:6647 (Apr 2015)<\/span><\/li>\n
                        17. Direct dry transfer of chemical vapor deposition graphene to polymeric substrates;<\/a><\/strong>
                          \nFechine, G. J. M., Martin-Fernandez, I., Yiapanis, G., Bentini, R., Kulkarni, E. S., de Oliveira, R. V. B., Hu, X., Yarovsky, I., Castro Neto, A. H., and \u00d6zyilmaz, B.
                          \nCarbon, 83 224-231 (Mar 2015)<\/span><\/li>\n
                        18. Conductance oscillations induced by ballistic snake states in a graphene heterojunction;<\/a><\/strong>
                          \nTaychatanapat, T., Tan, J., Y., Yeo, Y., Watanabe, K., Taniguchi, T., and \u00d6zyilmaz, B.
                          \nNature Comms., 6:6093 (Feb 2015)<\/span><\/li>\n
                        19. Quantum Transport and Observation of Dyakonov-Perel Spin-Orbit Scattering in Monolayer MoS2;<\/a><\/strong>
                          \nSchmidt, H., Yudhistira, I., Chu, L., Neto, A. H. C., \u00d6zyilmaz, B., Adam, S., and Eda, G.
                          \nPhys. Rev. Lett., 116 046803 (Jan 2015)<\/span><\/li>\n
                        20. Dynamical spin injection at a quasi-one-dimensional ferromagnet-graphene interface;<\/a><\/strong>
                          \nSingh, S., Ahmadi, A., Cherian, C. T., Mucciolo, E. R., del Barco, E., and \u00d6zyilmaz, B.
                          \nAppl. Phys. Lett., 106 032411 (Jan 2015)<\/span><\/li>\n
                        21. van der Waals Force: A Dominant Factor for Reactivity of Graphene;<\/a><\/strong>
                          \nLee, J. H., Avsar, A., Jung, J., Tan, J. Y., Watanabe, K., Taniguchi, T., Natarajan, S., Eda, G., Adam, S., Castro Neto, A. H., and \u00d6zyilmaz, B.
                          \nNano Letters, 15 (1) 319\u2013325 (Jan 2015)<\/span><\/li>\n
                        22. \u2018Bubble-free\u2019 electrochemical delamination of CVD graphene films;<\/a><\/strong>
                          \nCherian C. T., Giustiniano, F., Martin-Fernandez, I., Andersen, H., Balakrishnan, J., and \u00d6zyilmaz, B.
                          \nSmall, 11 (2) 189-194 (Jan 2015)<\/span><\/li>\n
                        23. Exploiting the IR-transparency of Graphene for Fast Pyroelectric Infrared Detection;<\/a><\/strong>
                          \nKulkarni, E.S., Heussler, S.P,. Stier, A.V., Martin-Fernandez, I., Andersen, H., Toh, C.T., and \u00d6zyilmaz, B.
                          \nAdv. Opt. Mater., 3 (1) 34-38 (Jan 2015)<\/span><\/li>\n<\/ol>\n

                          <\/h4>\n

                          2014<\/strong><\/h4>\n
                            \n
                          1. Charge transport in ion-gated mono-, bi-, and trilayer MoS2 field effect transistors;<\/a><\/strong>
                            \nChu, L., Schmidt, H., Pu, J., Wang, S., Takenobu, T., Eda, G., and \u00d6zyilmaz, B.
                            \nSci. Reports, 4:7293 (Dec 2014)<\/span><\/li>\n
                          2. Spin-Orbit Proximity Effect in Graphene;<\/a><\/strong>
                            \nAvsar, A., Tan, J. Y., Balakrishnan, J., Koon, G. K. W., Lahiri, J., Carvalho, A., Rodin, A. S., Taychatanapat, T., O\u2019Farrell, E. C. T., Eda, G., Castro Neto, A. H., and \u00d6zyilmaz, B.
                            \nNature Comms., 5:4875 (Sep 2014)<\/span><\/li>\n
                          3. Giant Spin Hall Effect in Graphene Grown by Chemical Vapor Deposition;<\/a><\/strong>
                            \nBalakrishnan, J., Koon, G. K. W., Avsar, A., Ho, Y., Lee, J. H., Jaiswal, M., Baeck, S-J., Ahn, J-H., Ferreira, A., Cazalilla, M. A., Castro Neto, A. H., and \u00d6zyilmaz, B.
                            \nNature Comms., 5:4748 (Sep 2014)<\/span><\/li>\n
                          4. Unconventional Transport through Graphene on SrTiO3: A Plausible Effect of SrTiO3 Phase-Transitions;<\/a><\/strong>
                            \nSaha, S., Kahya, O., Jaiswal, M., Srivatsava, A., Annadi, A., Balakrishnan, J., Pachoud, A., Toh, C. T., Hong, B-H., Ahn, J-H., Venkatesan, T. and \u00d6zyilmaz, B.
                            \nScientific Reports, 4:6173 (Aug 2014)<\/span><\/li>\n
                          5. Scattering theory of spin-orbit active adatoms on graphene;<\/a><\/strong>
                            \nPachoud, A., Ferreira, A., \u00d6zyilmaz, B. and Castro Neto, A. H.
                            \nPhysical Review B 90, 035444 (Aug 2014)<\/span><\/li>\n
                          6. Electronic transport in graphene-based heterostructures;<\/a><\/strong>
                            \nTan, J. Y., Avsar, A., Balakrishnan, J., Koon, G. K. W., Taychatanapat, T., O\u2019Farrell, E. C. T., Watanabe, K., Taniguchi, T., Eda, G., Neto, A. H. C., and \u00d6zyilmaz, B.
                            \nAppl. Phys. Lett. 104, 183504 (May 2014)<\/span><\/li>\n
                          7. Nanometer Thick Elastic Graphene Engine;<\/a><\/strong>
                            \nLee, J. H., Tan, J. Y., Toh, C. T., Koenig, S. P., Fedorov, V. E., Castro Neto, A. H., and \u00d6zyilmaz, B.
                            \nNano Lett. 14 (5), 2677\u20132680 (Apr 2014)<\/span><\/li>\n
                          8. Large Thermoelectricity via Variable Range Hopping in CVD Grown Single-layer MoS2<\/sub>;<\/a><\/strong>
                            \nJing, W., Schmidt, H., Amara, K., Xu, X., Eda, G., and \u00d6zyilmaz, B.
                            \nNano Lett. 14 (5), 2730\u20132734 (Apr 2014)<\/span><\/li>\n
                          9. Length-dependent thermal conductivity in suspended single-layer graphene;<\/a><\/strong>
                            \nXu, X., Pereira, L. F. C., Wang, Y., Wu, J., Zhang, K., Zhao, X., Bae, S., Tinh Bui, C., Xie, R., Thong, J. T. L., Hong, B. H., Loh, K. P., Donadio, D., Li, B., and \u00d6zyilmaz, B.
                            \nNature Comms. 5:3689, (Apr 2014)<\/span><\/li>\n
                          10. Ultrathin Organic Solar Cells with Graphene Doped by Ferroelectric Polarization;<\/a><\/strong>
                            \nKim, K., Bae, S.-H., Toh, C. T., Kim, H., Cho, J. H., Whang, D., Lee, T.-W., \u00d6zyilmaz, B., and Ahn, J.-H.
                            \nACS Appl. Mat. & Inter. 6(5), 3299-3304 (Mar 2014)<\/span><\/li>\n
                          11. Electric field effect in ultrathin black phosphorus;<\/a><\/strong>
                            \nKoenig, S. P., Doganov, R. A., Schmidt, H., Castro Neto, A. H., and \u00d6zyilmaz, B.
                            \nAppl. Phys. Lett. 104, 103106 (Mar 2014)<\/span><\/li>\n
                          12. Transport properties of monolayer MoS2<\/sub>\u00a0<\/span>grown by chemical vapour deposition;<\/a><\/strong>
                            \nSchmidt, H., Wang, S., Chu, L., Toh, M., Kumar, R., Zhao, W., Castro Neto, A. H., Martin, J., Adam, S., \u00d6zyilmaz, B., and Eda, G.
                            \nNano Lett. 14 (4), 1909\u20131913 (Mar 2014)<\/span><\/li>\n<\/ol>\n

                            <\/h4>\n

                            2013<\/strong><\/h4>\n
                              \n
                            1. Tuning Optical Conductivity of Large-Scale CVD Graphene by Strain Engineering;<\/a><\/strong>
                              \nNi, G. X., Yang, H. Z., Ji, W., Baeck, S. J., Toh, C. T., Ahn, J. H., Pereira, V. M. and \u00d6zyilmaz, B.
                              \nAdvanced Materials 26 (7), 10.1002\/adma.201304156 (Dec 2013).<\/span>><\/li>\n
                            2. Multiple Virtual Tunneling of Dirac Fermions in Granular Graphene;<\/a><\/strong>
                              \nPachoud, A., Jaiswal, M., Wang, Y., Hong, B.-H., Ahn, J.-H., Loh, K. P. and \u00d6zyilmaz, B.
                              \nScientific Reports 3:3404 (Dec 2013).<\/span><\/li>\n
                            3. Flexible graphene\u2013PZT ferroelectric nonvolatile memory;<\/a><\/strong>
                              \nLee, W., Kahya, O., Toh, C. T., \u00d6zyilmaz, B. and Ahn, J.-H.
                              \nNanotechnology, Volume 24, Issue 47 (Sep 2013).<\/span><\/li>\n
                            4. Property Control of Graphene by Employing \u201cSemi-Ionic\u201d Liquid Fluorination;<\/a><\/strong>
                              \nLee, J. H., Koon, G. K. W., Shin, D. W., Fedorov, V. E., Choi, J.-Y., Yoo, J.-B. and \u00d6zyilmaz, B.
                              \nAdvanced Functional Materials, Volume 23, Issue 26, pp 3329\u20133334 (July 2013).<\/span><\/li>\n
                            5. Spin Pumping in Permalloy\/Graphene and Permalloy\/Graphite Interfaces;<\/a><\/strong>
                              \nSingh, S., Patra, A. K., Barin, B., del Barco, E., and \u00d6zyilmaz, B.
                              \nIEEE Transactions on Magnetics, Volume 49, Issue 7, pp 3147-3150 (July 2013).<\/span><\/li>\n
                            6. Scrolling graphene into nanofluidic channels;<\/a><\/strong>
                              \nMirsaidov, U., Mokkapati, V. R. S. S., Bhattacharya, D., Andersen, H., Bosman, M., \u00d6zyilmaz, B. and Matsudaira, P.
                              \nLab on a Chip, Volume 13, Issue 15, pp 2874-2878 (May 2013).<\/span><\/li>\n
                            7. Colossal Enhancement of Spin-Orbit Coupling in Weakly Hydrogenated Graphene;<\/a><\/strong>
                              \nBalakrishnan, J., Koon, G. K. W., Jaiswal, M., Castro Neto, A. H., \u00d6zyilmaz, B.
                              \nNature Physics 9, pp 284\u2013287 (May 2013).<\/span><\/li>\n
                            8. An innovative way of etching MoS2: Characterization and mechanistic investigation;<\/a><\/strong>
                              \nHuang, Y., Wu , J., Xu, X., Ho, Y., Ni, G. X., Zou, Q., Koon, G. K. W., Zhao, W., Castro Neto, A. H., Eda, G., Shen, C., \u00d6zyilmaz, B.
                              \nNano Research, Volume 6, Issue 3, pp 200-207 (Mar 2013).<\/span><\/li>\n
                            9. Graphene-P(VDF-TrFE) multilayer film for flexible applications;<\/a><\/strong>
                              \nBae, S.-H., Kahya, O., Sharma, B. K., Kwon, J. G., Cho, H. J., \u00d6zyilmaz, B., Ahn, J.-H.
                              \nACS Nano, Volume 7, Issue 4, pp 3130\u20133138 (Feb 2013).<\/span><\/li>\n<\/ol>\n

                              <\/h4>\n

                              2012<\/strong><\/h4>\n
                                \n
                              1. Localized insulator-conductor transformation of graphene oxide thin films via focused laser beam irradiation;<\/a><\/strong>
                                \nTao, Y., Varghese, B., Jaiswal, M., Wang, S., Zhang, Z., \u00d6zyilmaz, B., Loh, K.P., Tok, E.S., Sow, C.H.
                                \nApplied Physics A: Materials Science and Processing, 106 (3), pp 523-531 (2012).<\/span><\/li>\n
                              2. Dynamic spin injection into chemical vapor deposited graphene;<\/a><\/strong>
                                \nA. K. Patra, S. Singh, B. Barin, Y. Lee, J.-H. Ahn, E. del Barco, E. R. Mucciolo, and B. \u00d6zyilmaz
                                \nApplied Physics Letters 101, 162407 (2012).<\/span><\/li>\n
                              3. Assembly of suspended graphene on carbon nanotube scaffolds with improved functionalities;<\/a><\/strong>
                                \nSharon Xiaodai Lim, Gavin Kok Wai Koon, Da Zhan, Zexiang Shen, B. \u00d6zyilmaz, Chornghaur Sow
                                \nNano Research, 1998-0124 (2012).<\/span><\/li>\n
                              4. Graphene\u2013Ferroelectric Hybrid Structure for Flexible Transparent Electrodes;<\/a><\/strong>
                                \nG.-X. Ni, Y. Zheng, S. Bae, C.Y. Tan, O. Kahya, J. Wu, B.H. Hong, K. Yao, B. \u00d6zyilmaz
                                \nACS Nano, 6 (5), pp 3935\u20133942 (2012).<\/span><\/li>\n
                              5. Quasi-Periodic Nanoripples in Graphene Grown by Chemical Vapor Deposition and Its Impact on Charge Transport;<\/a><\/strong>
                                \nG.-X. Ni, Y. Zheng, S. Bae, H.R. Kim, A. Pachoud, Y.S. Kim, C.-L. Tan, D. Im, J.-H. Ahn, B.H. Hong, B. \u00d6zyilmaz
                                \nACS Nano, 6 (2), pp 1158\u20131164 (2012).
                                \n<\/span><\/li>\n
                              6. Electronic Properties of Nanodiamond Decorated Graphene;<\/a><\/strong>
                                \nY. Wang, M. Jaiswal, M. Lin, S. Saha, B. \u00d6zyilmaz, K.P. Loh
                                \nACS Nano, 6 (2), pp 1018\u20131025 (2012).<\/span><\/li>\n<\/ol>\n

                                <\/h4>\n

                                2011<\/strong><\/h4>\n
                                  \n
                                1. Observation of Long Spin Relaxation Times in Bilayer Graphene at Room Temperature;<\/a><\/strong>
                                  \nT.-Y. Yang, J. Balakrishnan, F. Volmer, A. Avsar, M. Jaiswal, J. Samm, S.R. Ali, A.Pachoud, M. Zeng, M. Popinciuc, G. G\u00fcntherodt, B. Beschoten & B. \u00d6zyilmaz
                                  \nPhys. Rev. Lett. 107, 047206 (2011).<\/span><\/li>\n
                                2. Electrical measurement of non-destructively p-journal article doped graphene using molybdenum trioxide;<\/a><\/strong>
                                  \nLanfei Xie, Xiao Wang, Hongying Mao, Rui Wang, Mianzhi Ding, Yu Wang, Barbaros \u00d6zyilmaz, Kian Ping Loh, Andrew T. S. Wee, Ariando and Wei Chen
                                  \nAppl. Phys. Lett. 99(1) 012112-012115 (2011).
                                  \n<\/span><\/li>\n
                                3. Interface Engineering of Layer-by-Layer Stacked Graphene Anodes for High-Performance Organic Solar Cells;<\/a><\/strong>
                                  \nWang, Yu, Shi Wun Tong, Xiang Fan Xu, Barbaros \u00d6zyilmaz and Kian Ping Loh
                                  \nAdvanced Materials 23(13) 1514-1518 (2011) Cover Article.
                                  \n<\/span><\/li>\n
                                4. Room temperature ferromagnetism in partially hydrogenated epitaxial graphene;<\/a><\/strong>
                                  \nLanfei Xie, Xiao Wang, Jiong Lu, Zhenhua Ni, Zhiqiang Luo, Hongying Mao, Rui Wang, Yingying Wang, Han Huang, Dongchen Qi, Rong Liu, Ting Yu, Zexiang Shen, Tom Wu, Haiyang Peng, Barbaros \u00d6zyilmaz, Kianping Loh, Andrew T. S. Wee, Ariando and Wei Chen
                                  \nApplied Physics Letters 98(19) 193113-193115 (2011).
                                  \n<\/span><\/li>\n
                                5. Graphene for Controlled and Accelerated Osteogenic Differentiation of Human Mesenchymal Stem Cells;<\/a><\/strong>
                                  \nTapas R. Nayak, Henrik Andersen, Venkata S. Makam, Clement Khaw, Sukang Bae, Xiangfan Xu, Pui-Lai R. Ee, Jong-Hyun Ahn, Byung Hee Hong, Giorgia Pastorin & Barbaros \u00d6zyilmaz
                                  \nACS Nano 5(6) 4670\u20134678 (2011).
                                  \n<\/span><\/li>\n
                                6. Towards wafer scale fabrication of graphene based spin valve devices;<\/a><\/strong>
                                  \nAhmet Avsar, Tsung-Yeh Yang, Su-Kang Bae, Jayakumar Balakrishnan, Frank Volmer, Manu Jaiswal, Zheng Yi, Syed Rizwan Ali, Gernot G\u00fcntherodt, Byung-Hee Hong, Bernd Beschoten & Barbaros \u00d6zyilmaz
                                  \nNano Lett. 11(6) 2363\u20132368 (2011).
                                  \n<\/span><\/li>\n
                                7. A new route to graphene layers by selective laser ablation;<\/a><\/strong>
                                  \nDhar S., A. Roy Barman, G. X. Ni, X. Wang, X. F. Xu, Y. Zheng, S. Tripathy, Ariando, A. Rusydi, K. P. Loh, M. Rubhausen, A. H. Castro Neto, B. \u00d6zyilmaz & T. Venkatesan
                                  \nAIP Advances 1(2) 022109-022108 (2011).
                                  \n<\/span><\/li>\n
                                8. Controlled Hydrogenation of Graphene Sheets and Nanoribbons;<\/a><\/strong>
                                  \nManu Jaiswal, Candy Haley Yi Xuan Lim, Qiaoliang Bao, Chee Tat Toh, Kian Ping Loh & Barbaros \u00d6zyilmaz
                                  \nACS Nano 5(2) 888-896 (2011).
                                  \n<\/span><\/li>\n
                                9. Transport properties of graphene with one-dimensional charge defects;<\/a><\/strong>
                                  \nA. Ferreira, X. Xu, C.-L. Tan, S. Bae, N. M. R. Peres, B.-H. Hong, B. \u00d6zyilmaz & A. H. Castro Neto.
                                  \nEPL (Europhysics Letters) 94(2) 28003 (2011)
                                  \n<\/span><\/li>\n
                                10. Wafer-scale graphene\/ferroelectric hybrid devices for low-voltage electronics;<\/a><\/strong>
                                  \nYi Zheng, Guang-Xin Ni, Sukang Bae, Chun-Xiao Cong, Orhan Kahya, Chee-Tat Toh, Ri Kim Kim, Danho Im, Ting Yu, Jong-Hyun Ahn, Byung Hee Hong & Barbaros \u00d6zyilmaz
                                  \nEPL (Europhysics Letters) 93, 17002 (2011)<\/span><\/li>\n<\/ol>\n

                                  <\/h4>\n

                                  2010<\/strong><\/h4>\n
                                    \n
                                  1. Phonon Transport in Suspended Single Layer Graphene;<\/a><\/strong>
                                    \nXiangfan Xu, Yu Wang, Kaiwen Zhang, Xiangming Zhao, Sukang Bae, Martin Heinrich, Bui Cong Tinh, Rongguo Xie, John T. L. Thong, Byung Hee Hong, Kian Ping Loh, Baowen Li & Barbaros \u00d6zyilmaz
                                    \narXiv:1012.2937 [cond-mat.mes-hall] (2010)
                                    \n<\/span><\/li>\n
                                  2. A Bioelectronic Platform Using a Graphene\u2212Lipid Bilayer Interface;<\/a><\/strong>
                                    \nPriscilla Kailian Ang, Manu Jaiswal, Candy Haley Yi Xuan Lim, Yu Wang, Jagadish Sankaran, Ang Li, Chwee Teck Lim, Thorsten Wohland, Barbaros \u00d6zyilmaz & Kian Ping Loh.
                                    \nACS Nano 4, 7387-7394, doi:10.1021\/nn1022582 (2010)
                                    \n<\/span><\/li>\n
                                  3. Graphene Transport at High Carrier Densities using a Polymer Electrolyte Gate;<\/a><\/strong>
                                    \nA. Pachoud, M. Jaiswal, P. Kailian Ang, K. P. Loh & B. \u00d6zyilmaz.
                                    \nEPL (Europhysics Letters) 92, 27001 (2010)
                                    \n<\/span><\/li>\n
                                  4. Graphene Field Effect Transistor with Ferroelectric Gating;<\/a><\/strong>
                                    \nYi Zheng, Guangxin Ni, Chee Tat Toh, Chin-Yaw Tan, Kui Yao, & Barbaros \u00d6ezyilmaz.
                                    \nPhysical Review Letters 105, 166602 (2010)
                                    \n<\/span><\/li>\n
                                  5. Toward High Throughput Interconvertible Graphane-to-Graphene Growth and Patterning;<\/a><\/strong>
                                    \nYu Wang, Xiangfan Xu, Jiong Lu, Ming Lin, Qiaoliang Bao, Barbaros \u00d6zyilmaz & Kian Ping Loh.
                                    \nACS Nano 4, 6146\u20136152, doi:10.1021\/nn1017389 (2010).
                                    \n<\/span><\/li>\n
                                  6. Roll-to-roll production of 30-inch graphene films for transparent electrodes;<\/a><\/strong>
                                    \nSukang Bae, Hyeongkeun Kim, Youngbin Lee, Xiangfan Xu, Jae-Sung Park, Yi Zheng, Jayakumar Balakrishnan, Tian Lei, Hye Ri Kim, Young Il Song, Young-Jin Kim, Kwang S. Kim, Barbaros Ozyilmaz, Jong-Hyun Ahn, Byung Hee Hong & Sumio Iijima.
                                    \nNature Nanotechnology 5, 574-578 (2010)
                                    \n<\/span><\/li>\n
                                  7. Dependence of quantum-Hall conductance on the edge-state equilibration position in a bipolar graphene sheet;<\/a><\/strong>
                                    \nDong-Keun Ki, Seung-Geol Nam, Hu-Jong Lee, Barbaros \u00d6zyilmaz.
                                    \nPhysical Review B 81, 033301 (2010).<\/span><\/li>\n<\/ol>\n

                                    <\/h4>\n

                                    2009<\/strong><\/h4>\n
                                      \n
                                    1. Gate-controlled nonvolatile graphene-ferroelectric memory;<\/a><\/strong>
                                      \nYi Zheng, Guang-Xin Ni, Chee-Tat Toh, Ming-Gang Zeng, Shu-Ting Chen, Kui Yao, Barbaros \u00d6zyilmaz.
                                      \nApplied Physics Letters 94, 163505-163503 (2009).<\/span><\/li>\n<\/ol>\n

                                      <\/h4>\n

                                      2008<\/strong><\/h4>\n
                                        \n
                                      1. Brillouin scattering study of low-frequency bulk acoustic phonons in multilayer graphene;<\/a><\/strong>
                                        \nZ. K. Wang, H. S. Lim, S. C. Ng, B. \u00d6zyilmaz & M. H. Kuok.
                                        \nCarbon 46, 2133-2136, doi: 10.1016\/j.carbon.2008.09.028 (2008).<\/span><\/li>\n
                                      2. Current saturation in zero-bandgap, top-gated graphene field-effect transistors;<\/a><\/strong>
                                        \nInanc Meric, Melinda Y. Han, Andrea F. Young, Barbaros \u00d6zyilmaz, Philip Kim, Kenneth L. Shepard.
                                        \nNature Nanotechnology 3, 654 \u2013 659 (2008).<\/span><\/li>\n
                                      3. Geometrical control of the magnetization direction in high aspect-ratio PdNi ferromagnetic nanoelectrodes;<\/a><\/strong>
                                        \nJ. C. Gonzalez-Pons, J. J. Henderson, E. del Barco, B. \u00d6zyilmaz.
                                        \nPhys. Rev. B 78, 012408 (2008).<\/span><\/li>\n<\/ol>\n

                                        <\/h4>\n

                                        2007<\/strong><\/h4>\n
                                          \n
                                        1. Electronic transport in locally gated graphene nanoconstrictions;<\/a><\/strong>
                                          \nB. \u00d6zyilmaz, P. Jarillo-Herrero, D. Efetov, P. Kim.
                                          \nApplied Physics Letters 91 , 192107 (2007).<\/span><\/li>\n
                                        2. Electronic transport and quantum Hall effect in bipolar graphene p-n-p junctions;<\/a><\/strong>
                                          \nB. \u00d6zyilmaz, P. Jarillo-Herrero, D. Efetov, D. A. Abanin, L. S. Levitov, P. Kim.
                                          \nPhys. Rev. Lett. 99 , 166804 (2007)<\/span><\/li>\n
                                        3. Energy Band Gap Engineering of Graphene Nanoribbons;<\/a><\/strong>
                                          \nM. Y. Han, B. \u00d6zyilmaz, Y. Zhang, Philip Kim.
                                          \nPhys. Rev. Lett. 98, 206805 (2007).<\/span><\/li>\n
                                        4. Fabrication of nanostencil masks for spin transfer torque studies via focused ion beam milling;<\/a><\/strong>
                                          \nB. \u00d6zyilmaz et al..
                                          \nJ. Appl. Phys. 101, 063920 (2007).<\/span><\/li>\n<\/ol>\n

                                          <\/h4>\n

                                          2006<\/strong><\/h4>\n
                                            \n
                                          1. Current induced switching in single ferromagnetic layer pillar junctions;<\/a><\/strong>
                                            \nB. \u00d6zyilmaz and A. D. Kent.
                                            \nAppl. Phys. Lett. 88, 162506 (2006).<\/span><\/li>\n<\/ol>\n

                                            <\/h4>\n

                                            2005<\/strong><\/h4>\n
                                              \n
                                            1. Bipolar Current Induced Excitations in High Magnetic Fields in Co\/Cu\/Co Bilayer Nanopillars;<\/a><\/strong>
                                              \nB. \u00d6zyilmaz, A. D. Kent, J. Z. Sun, M. J. Rooks, and R. H. Koch.
                                              \nPhys. Rev. B, Rap. Com. 71, 140403 (2005).<\/span><\/li>\n
                                            2. Spin-Transfer-Induced Magnetic Excitation: The role of spin-pumping induced damping;<\/a><\/strong>
                                              \nJ. Z. Sun, B. \u00d6zyilmaz, W. Chen, M. Tsoi, and A. D. Kent.
                                              \nJ. Appl. Phys. 97, 10C714 (2005).<\/span><\/li>\n<\/ol>\n

                                              <\/h4>\n

                                              2004<\/strong><\/h4>\n
                                                \n
                                              1. Current-Induced Effective Magnetic Fields in Co\/Cu\/Co Nanopillars;<\/a><\/strong>
                                                \nM. A. Zimmler, B. \u00d6zyilmaz, W. Chen, A. D. Kent, J. Z. Sun, M. J. Rooks, R. H. Koch.
                                                \nPhys. Rev. B 70, 184438 (2004).<\/span><\/li>\n
                                              2. Current Induced Excitations in Single Cobalt Ferromagnetic Layer Nanopillars;<\/a><\/strong>
                                                \nB. \u00d6zyilmaz, A. D. Kent, J. Z. Sun, M. J. Rooks and R. H. Koch.
                                                \nPhys. Rev. Lett. 93, 176604 (2004).<\/span><\/li>\n
                                              3. Lateral Photoelectric Effect Studies of a Two-Dimensional Electron Gas under Quantum Hall Conditions;<\/a><\/strong>
                                                \nH. van Zalinge , R.W. van der Heijden, J.H.Wolter, B. \u00d6zyilmaz, A. B\u00d6hm, and P. Wyder.
                                                \nSemiconductor Science and Technology (2004).<\/span><\/li>\n
                                              4. Spin-transfer-induced precessional magnetization reversal;<\/a><\/strong>
                                                \nA. D. Kent, B. \u00d6zyilmaz and E. del Barco.
                                                \nAppl. Phys. Lett. 84 (19) 3897 (2004).<\/span><\/li>\n<\/ol>\n

                                                <\/h4>\n

                                                2003<\/strong><\/h4>\n
                                                  \n
                                                1. Current-Induced Magnetization Reversal in High Magnetic Fields in Co\/Cu\/Co Nanopillars;<\/a><\/strong>
                                                  \nB. \u00d6zyilmaz, A. D. Kent, D. Monsma, J. Z. Sun, M. J. Rooks, and R. H. Koch.
                                                  \nPhys. Rev. Lett. 91, 067203 (2003).<\/span><\/li>\n
                                                2. Spin-torque Transfer in Batch Fabricated Spin-Valve Magnetic Nanojunctions;<\/a><\/strong>
                                                  \nJ. Z. Sun, D. J. Monsma, T. S. Kuan, M. J. Rooks, D.W. Abraham, B. \u00d6zyilmaz, A. D. Kent, and R. H. Koch.
                                                  \nJ. Appl. Phys. 93, 6859 (2003).<\/span><\/li>\n<\/ol>\n

                                                  <\/h4>\n

                                                  2001<\/strong><\/h4>\n
                                                    \n
                                                  1. Observation of the Screening Signature in the Lateral Photovoltage of Electrons in the Quantum Hall Regime;<\/a><\/strong>
                                                    \nH.van Zalinge, B. \u00d6zyilmaz, A. B\u00d6hm, R.W. van der Heijden, J.H. Wolter, P. Wyder.
                                                    \nPhys. Rev. B 64, 235303 (2001).<\/span><\/li>\n
                                                  2. Growth and Magnetotransport Study of Thin Ferromagnetic CrO2 (100) Films on Al2O3 (0001) Substrates;<\/a><\/strong>
                                                    \nM. Rabe, J. Pommer, K. Samm, B. \u00d6zyilmaz, M. Fraune, U. R\u00fcdiger, G. G\u00fcntherodt, S. Senz, D. Hesse.
                                                    \nJ. Phys.: Condens. Matter 14, 7 (2001).<\/span><\/li>\n
                                                  3. Shape Dependent Magnetization Reversal Processes and Flux Closure Configurations of Microstructured Epitaxial Fe(110) Elements;<\/a><\/strong>
                                                    \nC. K\u00d6nig, M. Sperlich, R. Heinesch, R. Calarco, J. O. Hauch, U. R\u00fcdiger, G. G\u00fcntherodt, B. \u00d6zyilmaz, A. D. Kent.
                                                    \nAppl. Phys. Lett. 79, 3648 (2001).<\/span><\/li>\n
                                                  4. Extrinsic and Intrinsic Magnetoresitance Contributions of Chromium Dioxide Thin Films;<\/a><\/strong>
                                                    \nU. R\u00fcdiger, M. Rabe, K. Samm, B. \u00d6zyilmaz, J. Pommers, G. G\u00fcntherodt.
                                                    \nJ. Appl. Phys. 89, 7699 (2001).<\/span><\/li>\n
                                                  5. Charge Screening in the Quantum Hall Regime Probed by the Lateral Photoelectric Effect;<\/a><\/strong>
                                                    \nH. van Zalinge, B. \u00d6zyilmaz, A. B\u00d6hm, R.W. van der Heijden, J.H. Wolter, and P.Wyder.
                                                    \nPhysica B. 298, 60 (2001).<\/span><\/li>\n<\/ol>\n","protected":false},"excerpt":{"rendered":"

                                                    GOOGLE SCHOLAR 2026 3D interconnected pore networks enable superior volumetric CO2 uptake in amine-functionalized nanoporous carbon for direct air capture…<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_acf_changed":false,"footnotes":""},"class_list":["post-10","page","type-page","status-publish","hentry"],"yoast_head":"\nPublications - Barbaros Group<\/title>\n<meta name=\"robots\" content=\"index, follow, max-snippet:-1, max-image-preview:large, max-video-preview:-1\" \/>\n<link rel=\"canonical\" href=\"https:\/\/graphene.nus.edu.sg\/barbaros\/publications\/\" \/>\n<meta property=\"og:locale\" content=\"en_US\" \/>\n<meta property=\"og:type\" content=\"article\" \/>\n<meta property=\"og:title\" content=\"Publications - Barbaros Group\" \/>\n<meta property=\"og:description\" content=\"GOOGLE SCHOLAR 2026 3D interconnected pore networks enable superior volumetric CO2 uptake in amine-functionalized nanoporous carbon for direct air capture...\" \/>\n<meta property=\"og:url\" content=\"https:\/\/graphene.nus.edu.sg\/barbaros\/publications\/\" \/>\n<meta property=\"og:site_name\" content=\"Barbaros Group\" \/>\n<meta property=\"article:modified_time\" content=\"2026-04-13T04:54:48+00:00\" \/>\n<meta name=\"twitter:card\" content=\"summary_large_image\" \/>\n<meta name=\"twitter:label1\" content=\"Est. reading time\" \/>\n\t<meta name=\"twitter:data1\" content=\"24 minutes\" \/>\n<script type=\"application\/ld+json\" class=\"yoast-schema-graph\">{\"@context\":\"https:\/\/schema.org\",\"@graph\":[{\"@type\":\"WebPage\",\"@id\":\"https:\/\/graphene.nus.edu.sg\/barbaros\/publications\/\",\"url\":\"https:\/\/graphene.nus.edu.sg\/barbaros\/publications\/\",\"name\":\"Publications - 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