Research Lab 

2022

• Ankit.**, Ho T.Y.K.*, Nirmal A.**, Kulkarni M.R.**, Accoto D., and Mathews N.~^ (2022) Soft Actuator Materials for Electrically Driven Haptic Interfaces. Advanced Intelligent Systems, 4, 2, 2100061. [IF: 7.4] ^##
• Li H., Liu M., Li M., Park H., Mathews N., Qi Y., Zhang X., Bolink H.J., Leo K., Graetzel M., and Yi C. (2022) Applications of vacuum vapor deposition for perovskite solar cells: A progress review. iEnergy, 1, 4, 434-452. [IF: N/A]
• Mishra J.K., Yantara N.**, Kanwat A.**, Furuhashi T., Ramesh S., Salim T., Jamaludin N.F.**, Febriansyah B., Ooi Z.E., Mhaisalkar S., Sum T.C., Hippalgaonkar K., and Mathews N.~^ (2022) Defect Passivation Using a Phosphonic Acid Surface Modifier for Efficient RP Perovskite Blue-Light-Emitting Diodes. ACS Applied Materials and Interfaces, 14, 30, 34238-34246.  [IF:9.5] ^##
• Kanwat A.**, Ghosh B.***, Ng S.E.**, Rana P.J.S.**, Lekina Y., Hooper T.J.N., Yantara N.**, Kovalev M., Chaudhary B., Kajal P., Febriansyah B., Tan Q.Y., Klein M., Shen Z.X., Ager J.W., Mhaisalkar S.G., and Mathews N.~^ (2022) Reversible Photochromism in ⟨110⟩ Oriented Layered Halide Perovskite. ACS Nano, 16, 2, 2942–2952. [IF:17.1] ^##
• Ramesh S., Giovanni D., Righetto M., Ye S., Fresch E., Wang Y., Collini E., Mathews N., and Sum T.C. (2022) Tailoring the Energy Manifold of Quasi-Two-Dimensional Perovskites for Efficient Carrier Extraction. Advanced Energy Materials, 12, 10, 2103556. [IF: 27.8] ^##
• Rana P.J.S.**, Febriansyah B., Koh T.M.**, Muhammad B.T., Salim T., Hooper T.J.N., Kanwat A.**, Ghosh B.**, Kajal P.*, Lew J.H.**, Aw Y.C., Yantara N.**, Bruno A., Pullarkat S.A., Ager J.W., Leong W.L., Mhaisalkar S.G., and Mathews N.~^ (2022) Alkali Additives Enable Efficient Large Area (>55 cm2) Slot‐Die Coated Perovskite Solar Modules. Advanced Functional Materials, 32, 22, 2113026. [IF: 19] ^##
• Koh T.M.**, Wang H., Ng Y.F., Bruno A., Mhaisalkar S., and Mathews N.~^ (2022) Halide Perovskite Solar Cells for Building Integrated Photovoltaics: Transforming Building Façades into Power Generators. Advanced Materials, 34, 25, 2104661. [IF: 29.4] ^##
• Cao J., Sim Y.**, Tan X.Y., Zheng J., Chien S.W., Jia N., Chen K., Tay Y.B.*, Dong J.-F., Yang L., Ng H.K., Liu H., Tan C.K.I., Xie G., Zhu Q., Li Z., Zhang G., Hu L., Zheng Y., Xu J., Yan Q., Loh X.J., Mathews N.~^, Wu J., and Suwardi A. (2022) Upcycling Silicon Photovoltaic Waste into Thermoelectrics. Advanced Materials, 34, 19, 2110518. [IF: 29.4] ^##
• Tay Y.B.*, Sim Y.**, Ang Koon Keong J.**, Iszaki Bin Patdillah M.**, Min Chua H., Tang Jun Jie E., Srinivasan M., and Mathews N.~^ (2022) Upcycling End of Life Solar Panels to Lithium-Ion Batteries Via a Low Temperature Approach. ChemSusChem, 15, 19, e202200978. [IF: 8.4] ^##
• Thambidurai M., Omer M.I., Shini F., Dewi H.A.*, Jamaludin N.F.**, Koh T.M.**, Tang X., Mathews N., and Dang C. (2022) Enhanced Thermal Stability of Planar Perovskite Solar Cells Through Triphenylphosphine Interface Passivation, ChemSusChem, 15, 8, e202102189. [IF: 8.4] ^##
• Thangavel N.R., Koh T.M.**, Chee Z.Q.**, Tay D.J.J.*, Lee M.J., Mhaisalkar S.G., Ager J.W., and Mathews N.~^ (2022) Printable Low-Temperature Carbon for Highly Efficient and Stable Mesoscopic Perovskite Solar Cells. Energy Technology, 10, 11, 2200559. [IF: 3.8]
• Kosasih F.U., Erdenebileg E., Mathews N., Mhaisalkar S.G., and Bruno A. (2022) Thermal evaporation and hybrid deposition of perovskite solar cells and mini-modules. Joule, 6, 12, 2692-2734. [IF: 39.8] ^##
• Pham H.K., Sim Y., Carboni M., Meyer D., and Mathews N.~^ (2022) Generating metal-organic frameworks (MOFs) from photovoltaic modules for wastewater remediation. Journal of Environmental Chemical Engineering, 10, 5, 108346. [IF: 7.7] ^#
• Shini F., Thambidurai M., Dewi H.A.**, Jamaludin N.F.**, Bruno A., Kanwat A.**, Mathews N., Dang C., and Nguyen H.D. (2022). Interfacial passivation with 4-chlorobenzene sulfonyl chloride for stable and efficient planar perovskite solar cells. Journal of Materials Chemistry C, 10, 23, 9044-9051. [IF: 6.4] ^##
• Febriansyah B.**, Li Y., Giovanni D., Salim T., Hooper T.J.N., Sim Y.**, Ma D., Laxmi S., Lekina Y., Koh T.M.**, Shen Z.X., Pullarkat S.A., Sum T.C., Mhaisalkar S.G., Ager J.W., and Mathews N.^ (2022) Inorganic frameworks of low-dimensional perovskites dictate the performance and stability of mixed-dimensional perovskite solar cells. Materials Horizons, 10, 2, 536-546. [IF: 13.3] ^##
• Ng S.E.**, Tay Y.B.*, Ho T.Y.K.*, Ankit.**, and Mathews N.~^ (2022) Inorganic electrochromic transistors as environmentally adaptable photodetectors. Nano Energy, 97, 107142. [IF: 17.6] ^##
• Fu J., Xu Q., Abdelwahab I., Cai R., Febriansyah B.*, Yin T., Loh K.P., Mathews N., Sun H., and Sum T.C. (2022) Strain propagation in layered two-dimensional halide perovskites. Science Advances, 8, 37, abq1971. [IF: 13.6] ^##
• Accoto D., Donadio A., Yang S., Ankit.**, and Mathews N. (2022) A Microfabricated Dual Slip-Pressure Sensor with Compliant Polymer-Liquid Metal Nanocomposite for Robotic Manipulation. Soft Robotics, 9, 3, 509-517. [IF: 7.9] ^##
• Tiwari N., Arianita Dewi H., Erdenebileg E., Narayan Chauhan R., Mathews N., Mhaisalkar S., and Bruno A. (2022) Advances and Potentials of NiOx Surface Treatments for P-i-n Perovskite Solar Cells. Solar RRL, 6, 3, 2100700. [IF: 7.9]
• Erdenebileg E., Wang H.**, Li J., Singh N., Dewi H.A.**, Tiwari N.**, Mathews N.^, Mhaisalkar S., and  Bruno A. (2022) Low-Temperature Atomic Layer Deposited Electron Transport Layers for Co-Evaporated Perovskite Solar Cells. Solar RRL, 6, 1, 2270011 [IF: 7.9]
• Dewi H.A.**, Li J., Erdenebileg E., Wang H., De Bastiani M., De Wolf S., Mathews N.~^, Mhaisalkar S., and Bruno A. (2022) Efficient bandgap widening in co-evaporated MAPbI3 perovskite. Sustainable Energy and Fuels, 6, 10, 2428-2438. [IF: 5.6] ^#

2021

• Han G.**, Koh T.M.**, Li J.**, Febriansyah B., Fang Y.**, Jamaludin N.F.**, Ng Y.F.**, Rana P.J.S.**, Mhaisalkar S., and  Mathews N.~^ (2021). ACS Applied Energy Materials, 4, 3, 2716-2723. [IF: 6.4] ^#
• Jamaludin N.F.**, Yantara N.**, Febriansyah B., Tay Y.B.*, Muhammad B.T., Laxmi S., Lim S.S., Sum T.C., Mhaisalkar S., and Mathews N.~^ (2021) Additives in Halide Perovskite for Blue-Light-Emitting Diodes: Passivating Agents or Crystallization Modulators?. ACS Energy Letters, 6, 12, 4265-4272. [IF: 22] ^##
• Febriansyah B., Lekina Y., Kaur J., Hooper T.J.N., Harikesh P.C.*, Salim T., Lim M.H., Koh T.M.**, Chakraborty S., Shen Z.X., Mathews N.~^, and England J. (2021) Formation of Corrugated n = 1 2D Tin Iodide Perovskites and Their Use as Lead-Free Solar Absorbers. ACS Nano, 15, 4, 6395-6409. [IF: 17.1] ^##
• Vashishtha P., Brown A.A.M.**, Pu S.H., Mhaisalkar S., and Mathews N.^ (2021) Tunable Electroluminescence for Pure White Emission From a Perovskite-Based LED. Advanced Electronic Materials, 7, 4, 2001227. [IF: 6.2] ^#
• Li J., Dewi H.A.**, Wang H.**, Zhao J., Tiwari N.*, Yantara N.**, Malinauskas T., Getautis V., Savenije T.J., Mathews N.^, Mhaisalkar S., and Bruno A. (2021). Advanced Functional Materials, 31, 42, 2103252.[ IF: 19] ^##
• Ng S.E.**, Yang J.**, John R.A.**, and Mathews N.~^ (2021) Adaptive Latent Inhibition in Associatively Responsive Optoelectronic Synapse. Advanced Functional Materials, 31, 28, 2100807. [IF: 19] ^##
• Dewi H.A.**, Li J., Wang H.**, Chaudhary B., Mathews N.~^, Mhaisalkar S., and Bruno A. (2021) Excellent Intrinsic Long-Term Thermal Stability of Co-Evaporated MAPbI3 Solar Cells at 85 °C. Advanced Functional Materials, 31, 22, 2100557. [IF: 19] ^##
• John R.A.**, Yantara N.**, Ng S.E.**, Patdillah M.I.B., Kulkarni M.R.**, Jamaludin N.F.**, Basu J., Ankit.*, Mhaisalkar S.G., Basu A., and Mathews N.~^ (2021)  Diffusive and Drift Halide Perovskite Memristive Barristors as Nociceptive and Synaptic Emulators for Neuromorphic Computing. Advanced Materials, 33, 15, 2007851. [IF: 29.4] ^##
• Jamaludin N.F.**, Febriansyah B., Ng Y.F.**, Yantara N.**, Li M., Giovanni D., Fu J., Tay Y.B.*, Baikie T., Sum T.C., Mathews N.~^, and Mhaisalkar S. (2021) Molecular design of two-dimensional perovskite cations for efficient energy cascade in perovskite light-emitting diodes. Applied Physics Letters, 119, 15, 154101. [IF: 4.0] ^##
• Brown A.A.M.**, Mathews N.~^, Vashishtha P., Hooper T.J.N., Ng Y.F., Nutan G.V., Fang Y., Giovanni D., Tey J.N., Jiang L., Damodaran B., Sum T.C., Pu S.H., and Mhaisalkar S.G. (2021) Precise control of CsPbBr3 perovskite nanocrystal growth at room temperature: Size tunability and synthetic insights. Chemistry of Materials, 33, 7, 2387-2397. [IF: 8.6] ^##
• Foong J.**, Febriansyah B., Rana PJS.**, Koh TM.**,Tay DJJ.*, Bruno A., Mhaisalkar S., and Mathews N.~^ (2021) Effects of All-Organic Interlayer Surface Modifiers on the Efficiency and Stability of Perovskite Solar Cells. ChemSusChem, 14, 6, 1524-1533. [IF: 8.4] ^##
• Ho T.Y.K.*, Ankit.*, Febriansyah B., Yantara N.**, Pethe S.*, Accoto D., Pullarkat S.A., and Mathews N.~^ (2021) Inducing thermoreversible optical transitions in urethane-acrylate systemsviaionic via liquid incorporation for stretchable smart devices. Journal of Materials Chemistry A, 9, 23, 13615-13624. [IF: 11.9] ^##
• Maddalena F., Xie A., Chin X.Y.**, Begum R.**, Witkowski M.E., Makowski M., Mahler B., Drozdowski W., Springham S.V., Rawat R.S., Mathews N., Dujardin C., Birowosuto M.D., and  Dang C. (2021) Deterministic Light Yield, Fast Scintillation, and Microcolumn Structures in Lead Halide Perovskite Nanocrystals. Journal of Physical Chemistry C, 125, 25, 14082-14088. [IF: 3.7] ^#
• Shukla S., Koh T.M.**, Patidar R., Lew J.H., Kajal P., Mhaisalkar S.G., and Mathews N.~^ (2021) Suppressing the δ-Phase and Photoinstability through a Hypophosphorous Acid Additive in Carbon-Based Mixed-Cation Perovskite Solar Cells. Journal of Physical Chemistry C, 125, 12, 6585-6592. [IF: 3.7] ^#
• Jagadeeswararao M.**, Vashishtha P., Hooper T.J.N., Kanwat A.**, Lim J.W.M., Vishwanath S.K.**, Yantara N.**, Park T., Sum T.C., Chung D.S., Mhaisalkar S.G., and Mathews N.~^ (2021) One-Pot Synthesis and Structural Evolution of Colloidal Cesium Lead Halide-Lead Sulfide Heterostructure Nanocrystals for Optoelectronic Applications. Journal of Physical Chemistry Letters, 12, 39, 9569-9578. [IF: 5.7] ^##
• Wang H.**, Li J., Dewi H.A.**, Mathews N., Mhaisalkar S., and Bruno A. (2021) Colorful Perovskite Solar Cells: Progress, Strategies, and Potentials. Journal of Physical Chemistry Letters, 12, 4, 1321-1329. [IF: 5.7] ^##
• Kajal P., Lew J.H.**, Kanwat A.**, Rana P.J.S.**, Nutan G.V.**, Koh T.M.**, Mhaisalkar S.G., Powar S.**, and Mathews N.~^ (2021) Unveiling the role of carbon black in printable mesoscopic perovskite solar cells. Journal of Power Sources, 501, 230019. [IF: 9.2] ^##
• Ankit.**, Krisnadi F.*, Pethe S.*, Lim K.J.R., Kulkarni M.R.**, Accoto D., and Mathews N.~^ (2021) MXene incorporated polymeric hybrids for stiffness modulation in printed adaptive surfaces. Nano Energy, 90, 106548. [IF: 17.6] ^##
• Giovanni D., Ramesh S., Righetto M., Melvin Lim J.W., Zhang Q., Wang Y., Ye S., Xu Q., Mathews N., and Sum T.C. (2021) The Physics of Interlayer Exciton Delocalization in Ruddlesden-Popper Lead Halide Perovskites. Nano Letters, 21, 1, 405-413. [IF: 10.8] ^##
• Vashishtha P., Hooper T.J.N., Fang Y., Kathleen D., Giovanni D., Klein M., Sum T.C., Mhaisalkar S.G., Mathews N.^, and White T. (2021) Room temperature synthesis of low-dimensional rubidium copper halide colloidal nanocrystals with near unity photoluminescence quantum yield. Nanoscale, 13, 1, 59-65. [IF: 6.7] ^#
• John R.A.**, Shah N., Vishwanath S.K.**, Ng S.E.**, Febriansyah B.**, Jagadeeswararao M., Chang C.-H., Basu A., and Mathews N.~^ (2021) Halide perovskite memristors as flexible and reconfigurable physical unclonable functions. Nature Communications, 12, 3681. [IF: 16.6] ^##
• Sugathan V.**, Ghosh B.**, Harikesh P.C.*, Kotha V.**, Vashishtha P., Salim T., Yella A., and Mathews N.~^ (2021) Synthesis of bismuth sulphoiodide thin films from single precursor solution. Solar Energy, 230, 714-720. [IF: 6.7] ^#

2020

• Ng S., John R.A.**, Yang J.**, and Mathews N.~^ (2020) Forming-Less Compliance-Free Multistate Memristors as Synaptic Connections for Brain-Inspired Computing. ACS Applied Electronic Materials, 2, 3, 817-826. [IF: 4.7]
• Li J., Han G.**, Vergeer K., Dewi H.A.**, Wang H.**, Mhaisalkar S., Bruno A., and Mathews N. (2020) Interlayer Engineering for Flexible Large-Area Planar Perovskite Solar Cells. ACS Applied Energy Materials, 3, 1, 777-784. [IF: 6.4] ^#
• Ankit.*, Tiwari N.*, Ho F., Krisnadi F., Kulkarni M.R.**, Nguyen L.L., Koh S.J.A., and Mathews N.~^ (2020) High-k, Ultrastretchable Self-Enclosed Ionic Liquid-Elastomer Composites for Soft Robotics and Flexible Electronics. ACS Applied Materials and Interfaces, 12, 33, 37561-37570. [IF: 9.5] ^##
• Wang H.**, Dewi H.A.**, Koh T.M.**, Bruno A., Mhaisalkar S., and Mathews N.~^ (2020) Bifacial, Color-Tunable Semitransparent Perovskite Solar Cells for Building-Integrated Photovoltaics. ACS Applied Materials and Interfaces, 12, 1, 484-493. [IF: 9.5] ^##
• Begum R.**, Chin X.Y., Damodaran B., Hooper T.J.N., Mhaisalkar S., and Mathews N.~^ (2020) Cesium Lead Halide Perovskite Nanocrystals Prepared by Anion Exchange for Light-Emitting Diodes. ACS Applied Nano Materials, 3, 2, 1766-1774. [IF: 5.9] ^#
• Jamaludin N.F.**, Yantara N.**, Giovanni D., Febriansyah B., Tay Y.B.*, Salim T., Sum T.C., Mhaisalkar S., and Mathews N.~^ (2020) White Electroluminescence from Perovskite-Organic Heterojunction. ACS Energy Letters, 5, 8, 2690-2697. [IF: 22] ^##
• Febriansyah B., Koh T.M.**, Rana P.J.S.**, Hooper T.J.N., Ang Z.Z., Li Y., Bruno A., Gratzel M., England J., Mhaisalkar S.G., and Mathews N.~^ (2020) Hybrid 2D [Pb(CH3NH2)I2]nCoordination Polymer Precursor for Scalable Perovskite Deposition. ACD Energy Letters, 5, 7, 2305-2312. [IF: 22] ^##
• Kanwat A.**, Yantara N.**, Ng Y.F.*, Hooper T.J.N., Rana P.J.S.**, Febriansyah B., Harikesh P.C.*, Salim T., Vashishtha P., Mhaisalkar S.G., and Mathews N.~^ (2020) Stabilizing the Electroluminescence of Halide Perovskites with Potassium Passivation. ACS Energy Letters, 5, 6, 1804-1813. [IF: 22] ^##
• Yantara N.**, Jamaludin N.F.**, Febriansyah B., Giovanni D., Bruno A., Soci C., Sum T.C., Mhaisalkar S., and Mathews N.~^ (2020) Designing the Perovskite Structural Landscape for Efficient Blue Emission. ACS Energy Letters, 5, 5, 1593-1600. [IF: 22] ^##
• Thangavel N.R., Adhyaksa G.W.P., Dewi H.A.**, Tjahjana L., Bruno A., Birowosuto M.D., Wang H.**, Mathews N., and Mhaisalkar S. (2020) Disordered Polymer Antireflective Coating for Improved Perovskite Photovoltaics. ACS Photonics, 7, 8, 1971-1977. [IF: 7] ^#
• Brown A.A.M., Damodaran B., Jiang L., Tey J.N., Pu S.H., Mathews N., and Mhaisalkar S.G. (2020) Lead Halide Perovskite Nanocrystals: Room Temperature Syntheses toward Commercial Viability. Advanced Energy Materials, 10 , 34, 2001349. [IF: 27.8] ^##
• Mhaisalkar S.G., Mathews N., Bolink H.J., and Bahulayan D. (2020) Advances in Perovskite Optoelectronics: Bridging the Gap Between Laboratory and Fabrication. Advanced Energy Materials, 10, 13, 2000393. [IF: 27.8] ^##
• Xie L., Vashishtha P., Koh T.M.**, Harikesh P.C.*, Jamaludin N.F.**, Bruno A., Hooper T.J.N., Li J., Ng Y.F.*, Mhaisalkar S.G., and Mathews N.~^ (2020) Realizing Reduced Imperfections via Quantum Dots Interdiffusion in High Efficiency Perovskite Solar Cells. Advanced Materials, 32, 40, 2003296. [IF: 29.4]  ^##
• Krisnadi F.*, Nguyen L.L.*, Ankit.*, Ma J., Kulkarni M.R*., Mathews N.^, and Dickey M.D. (2020) Directed Assembly of Liquid Metal–Elastomer Conductors for Stretchable and Self-Healing Electronics. Advanced Materials, 32, 30, 2001642. [IF: 29.4] ^##
• Harikesh P.C.*, Surendran A., Ghosh B.**, John R.A.**, Moorthy A., Yantara N.**, Salim T., Thirumal K., Leong W.L., Mhaisalkar S., and Mathews N.~^ (2020) Cubic NaSbS2 as an Ionic–Electronic Coupled Semiconductor for Switchable Photovoltaic and Neuromorphic Device Applications. Advanced Materials, 32, 7, 1906976. [IF: 29.4] ^##
• Periyal S.S.*, Jagadeeswararao M., Ng S.E.**, John R.A.**, and Mathews N.~^ (2020) Halide Perovskite Quantum Dots Photosensitized-Amorphous Oxide Transistors for Multimodal Synapses. Advanced Materials Technologies, 5, 11, 2000514. [IF: 6.8]  ^##
• Febriansyah B., Borzda T., Cortecchia D., Neutzner S., Folpini G., Koh T.M.**, Li Y., Mathews N., Petrozza A., and England J. (2020) Metal Coordination Sphere Deformation Induced Highly Stokes-Shifted, Ultra Broadband Emission in 2D Hybrid Lead-Bromide Perovskites and Investigation of Its Origin. Angewandte Chemie - International Edition, 59, 27, 10791-10796. [IF: 16.6] ^##
• Ng Y.F.*, Febriansyah B., Jamaludin N.F.**, Giovanni D., Yantara N.**, Chin X.Y., Tay Y.B.*, Sum T.C., Mhaisalkar S., and Mathews N.~^ (2020) Design of 2D Templating Molecules for Mixed-Dimensional Perovskite Light-Emitting Diodes. Chemistry of Materials, 32, 19, 8097-8105. [IF: 8.6] ^##
• Ghosh B.**, Febriansyah B., Harikesh P.C.**, Koh T.M.**, Hadke S., Wong L.H., England J., Mhaisalkar S.G., and Mathews N.~^ (2020) Direct Band Gap Mixed-Valence Organic-inorganic Gold Perovskite as Visible Light Absorbers. Chemistry of Materials, 32, 15, 6318-6325. [IF: 8.6] ^##
• Febriansyah B., Neo C.S.D., Giovanni D., Srivastava S., Lekina Y., Koh T.M.**, Li Y., Shen Z.X., Asta M., Sum T.C., Mathews N.^, and England J. (2020) Targeted Synthesis of Trimeric Organic-Bromoplumbate Hybrids That Display Intrinsic, Highly Stokes-Shifted, Broadband Emission. Chemistry of Materials, 32, 11, 4431-4441. [IF: 8.6] ^##
• Febriansyah B., Lekina Y., Ghosh B.**, Harikesh P.C.*, Koh T.M.**, Li Y., Shen Z., Mathews N.^, and England J. (2020) Molecular Engineering of Pure 2D Lead-Iodide Perovskite Solar Absorbers Displaying Reduced Band Gaps and Dielectric Confinement. ChemSusChem, 13, 10, 2693-2701. [IF: 8.4] ^##
• Li J., Wang H.**, Dewi H.A.**, Mathews N.~^, Mhaisalkar S., and Bruno A. (2020) Potassium acetate-based treatment for thermally co-evaporated perovskite solar cells. Coatings, 10, 12, 1163. [IF: 3.4]
• Dewi H.A.**, Wang H.**, Li J., Thway M., Lin F., Aberle A.G., Mathews N.~^, Mhaisalkar S., and Bruno A. (2020) Four-Terminal Perovskite on Silicon Tandem Solar Cells Optimal Measurement Schemes. Energy Technology, 8, 4, 1901267. [IF: 3.8]
• Bin Suhaimi F., Palale S., Teh L.K., Mathews N., and Mhaisalkar S. (2020) Energy band and optical modeling of charge transport mechanism and photo-distribution of MoO3/Al-doped MoO3 in organic tandem cells. Functional Materials Letters, 13, 2, 2051003. [IF: 1.3]
• Tiwari N.*, Nirmal A.**, Kulkarni M.R.**, John R.A.**, and Mathews N.~^ (2020) Enabling high performance n-type metal oxide semiconductors at low temperatures for thin film transistors. Inorganic Chemistry Frontiers, 7, 9, 1822-1844. [IF: 7] ^##
• Li J., Wang H., Chin X.Y., Dewi H.A.**, Vergeer K., Goh T.W., Lim J.W.M., Lew J.H., Loh K.P., Soci C., Sum T.C., Bolink H.J., Mathews N.^, Mhaisalkar S., and Bruno A. (2020) Highly Efficient Thermally Co-evaporated Perovskite Solar Cells and Mini-modules. Joule, 4, 5, 1035-1053. [IF: 39.8] ^##
• Liang C., Salim K.M.M., Li P., Wang Z., Koh T.M.**, Gu H., Wu B., Xia J., Zhang Z., Wang K., Liu T., Wei Q., Wang S., Tang Y., Shao G., Song Y., Mathews N.^, and Xing G. (2020) Controlling the film structure by regulating 2D Ruddlesden-Popper perovskite formation enthalpy for efficient and stable tri-cation perovskite solar cells. Journal of Materials Chemistry A, 8, 12, 5874-5881. [IF: 11.9] ^##
• Vashishtha P., Veldhuis S.A., Dintakurti S.S.H., Kelly N.L., Griffith B.E., Brown A.A.M., Ansari M.S., Bruno A., Mathews N., Fang Y., White T., Mhaisalkar S.G., and Hanna J.V. (2020) Investigating the structure-function relationship in triple cation perovskite nanocrystals for light-emitting diode applications. Journal of Materials Chemistry C, 8, 34, 11805-11821. [IF: 6.4] ^##
• Du W., Nguyen A.C., John R.A.**, Yang J.J., Kulkarni M.R.**, Lopez-Mena E.R., Nirmal A.**, and Mathews N.^ (2020) Bilayer BaSnO3 thin film transistors on silicon substrates. Journal of Materials Chemistry C, 8, 15, 5231-5238. [IF: 6.4] ^##
• Febriansyah B., Giovanni D., Ramesh S., Koh T.M.**, Li Y., Sum T.C., Mathews N., and  England J. (2020) Inducing formation of a corrugated, white-light emitting 2D lead-bromide perovskite via subtle changes in templating cation. Journal of Materials Chemistry C, 8, 3, 889-893. [IF: 6.4] ^##
• Lim J.W.M., Giovanni D., Righetto M., Feng M., Mhaisalkar S.G., Mathews N., and Sum T.C. (2020) Hot Carriers in Halide Perovskites: How Hot Truly?. Journal of Physical Chemistry Letters, 11, 7, 2743-2750. [IF:5.7] ^##
• Thambidurai M., Febriansyah B., Foo S., Harikesh P.C.*, Ming K.T., Mathews N., and  Dang C. (2020) Enhanced stability and photovoltaic performance of planar perovskite solar cells through anilinium thiobenzoate interfacial engineering. Journal of Power Sources, 479, 228811.[IF: 9.2] ^##
• Foo S., Thambidurai M., Harikesh P.C.*, Mathews N., Huang Y., and Dang C. (2020) Interfacial 2-hydrozybenzophenone passivation for highly efficient and stable perovskite solar cells. Journal of Power Sources, 475,  228665. [IF: 9.2] ^##
• Sakthivel P., Foo S., Thambidurai M., Harikesh P.C.*, Mathews N., Yuvakkumar R., Ravi G., and Dang C. (2020) Efficient and stable planar perovskite solar cells using co-doped tin oxide as the electron transport layer. Journal of Power Sources, 471, 228443. [IF: 9.2] ^##
• Thambidurai M., Shini F., Harikesh P.C.*, Mathews N., and Dang C. (2020) Highly stable and efficient planar perovskite solar cells using ternary metal oxide electron transport layers. Journal of Power Sources, 448, 227362. [IF: 9.2] ^##
• Kulkarni S.A., Yantara N.**, Tan K.S., Mathews N.~^, and Mhaisalkar S.G. (2020) Perovskite nanostructures: Leveraging quantum effects to challenge optoelectronic limits. Materials Today, 33, 122-140. [IF: 24.2] ^##
• Tuchman Y., Mangoma T.N., Gkoupidenis P., Van De Burgt Y., John R.A.**, Mathews N., Shaheen S.E., Daly R., Malliaras G.G., and Salleo A. (2020) Organic neuromorphic devices: Past, present, and future challenges. MRS Bulletin, 45, 8, 619-630. [IF: 5] ^#
• Harikesh P.C.*, Febriansyah B., John R.A.**, and Mathews N.~^ (2020) Hybrid organic-inorganic halide perovskites for scaled-in neuromorphic devices. MRS Bulletin, 45, 8, 641-648. [IF: 5] ^#
• John R.A.**, Tiwari N.*, Patdillah M.I.B.**, Kulkarni M.R.**, Tiwari N.*, Basu J., Bose S.K., Ankit.*, Yu C.J., Nirmal A.**, Vishwanath S.K.**, Bartolozzi C., Basu A., and Mathews N.~^ (2020) Self healable neuromorphic memtransistor elements for decentralized sensory signal processing in robotics. Nature Communications,11, 1, 4030. [IF: 16.6] ^##
• John R.A.**, Acharya J., Zhu C., Surendran A., Bose S.K., Chaturvedi A., Tiwari N.*, Gao Y., He Y., Zhang K.K., Xu M., Leong W.L., Liu Z., Basu A., and Mathews N.~^ (2020) Optogenetics inspired transition metal dichalcogenide neuristors for in-memory deep recurrent neural networks. Nature Communications, 11, 1, 3211. [IF: 16.6] ^##
• Chaudhary B., Koh T.M.**, Febriansyah B., Bruno A., Mathews N., Mhaisalkar S.G., and Soci C. (2020) Publisher Correction: Mixed-Dimensional Naphthylmethylammonium-Methylammonium Lead Iodide Perovskites with Improved Thermal Stability. Scientific Reports, 10, 1, 8590. [IF: 4.6] ^#
• Chaudhary B., Koh T.M.**, Febriansyah B., Bruno A., Mathews N., Mhaisalkar S.G., and Soci C. (2020) Mixed-Dimensional Naphthylmethylammonium-Methylammonium Lead Iodide Perovskites with Improved Thermal Stability. Scientific Reports, 10, 1, 429. [IF: 4.6] ^#
• Li J., Dewi H.A.**, Wang H.**, Lew J.H., Mathews N.~^, Mhaisalkar S., and Bruno A. (2020) Design of Perovskite Thermally Co-Evaporated Highly Efficient Mini-Modules with High Geometrical Fill Factors. Solar RRL, 4, 12, 2000473. [IF: 7.9]

2019

• Dewi H.A.**, Wang H.**, Li J., Thway M., Sridharan R., Stangl R., Lin F., Aberle A.G., Mathews N., Bruno A., and Mhaisalkar S. (2019) Highly Efficient Semitransparent Perovskite Solar Cells for Four Terminal Perovskite-Silicon Tandems. ACS Applied Materials and Interfaces, 11, 37, 34178-34187. [IF: 9.5] ^##
• Guo X., Koh T.M.**, Febriansyah B., Han G.**, Bhaumik S., Li J., Jamaludin N.F.**, Ghosh B.**, Chen X., Mhaisalkar S., and Mathews N.~^ (2019) Cesium Oleate Passivation for Stable Perovskite Photovoltaics. ACS Applied Materials and Interfaces, 11, 31, 27882-27889. [IF: 9.5] ^##
• Ahmad R., Surendran A., Harikesh P.C.*, Haselsberger R., Jamaludin N.F.**, John R.A.**, Koh T.M.**, Bruno A., Leong W.L., Mathews N.^, Michel-Beyerle M.-E., and Mhaisalkar S.G. (2019) Perturbation-Induced Seeding and Crystallization of Hybrid Perovskites over Surface-Modified Substrates for Optoelectronic Devices. ACS Applied Materials and Interfaces, 11, 31, 27727-27734. [IF: 9.5] ^##
• Begum R.**, Chin X.Y., Li M., Damodaran B., Sum T.C., Mhaisalkar S., and Mathews N.~^ (2019) Stable Sn2+ doped FAPbI3 nanocrystals for near-infrared LEDs. Chemical Communications, 55, 38, 5451-5454. [IF: 4.9] ^##
• Cai Y., Xie W., Teng Y.T., Harikesh P.C.*, Ghosh B.**, Huck P., Persson K.A., Mathews N., Mhaisalkar S.G., Sherburne M., and Asta M. (2019) High-throughput Computational Study of Halide Double Perovskite Inorganic Compounds. Chemistry of Materials, 31, 15, 5392-5401. [IF: 8.6] ^##
• Vashishtha P., Nutan G.V., E. Griffith B., Fang Y., Giovanni D., Jagadeeswararao M., Sum T.C., Mathews N., Mhaisalkar S.G., Hanna J.V., and White T. (2019) Cesium Copper Iodide Tailored Nanoplates and Nanorods for Blue, Yellow, and White Emission. Chemistry of Materials, 31, 21, 9003-9011. [IF: 8.6] ^##
• Maitani M.M., Tateyama A., Boix P.P.**, Han G.**, Nitta A., Ohtani B., Mathews N., and Wada Y. (2019) Effects of energetics with {001} facet-dominant anatase TiO 2 scaffold on electron transport in CH 3 NH 3 PbI 3 perovskite solar cells. Electrochimica Acta, 300, 445-454. [IF: 6.6] ^#
• Gurudayal, Beeman J.W., Bullock J., Wang H.**, Eichhorn J., Towle C., Javey A., Toma F.M., Mathews N., and Ager J.W. (2019) Si photocathode with Ag-supported dendritic Cu catalyst for CO2 reduction. Energy and Environmental Science, 12, 3, 1068-1077. [IF:  32.5] ^##
• Filonik O., Thordardottir M.E., Lebert J., Proller S., Weiss S., Haur L.J.*, Priyadarshi A., Fontaine P., Muller-Buschbaum P., Mathews N., and Herzig E.M. (2019) Evolution of Perovskite Crystallization in Printed Mesoscopic Perovskite Solar Cells. Energy Technology, 7, 10, 1900343. [IF: 3.8]
• Hong Z., Tan D., John R.A.**, Tay Y.K.E., Ho Y.K.T., Zhao X., Sum T.C., Mathews N.^, Garcia F., and Soo H.S. (2019) Completely Solvent-free Protocols to Access Phase-Pure, Metastable Metal Halide Perovskites and Functional Photodetectors from the Precursor Salts. iScience, 16, 312-325. [IF: 5.8] ^#
• Thambidurai M., Foo S., Muhammed Salim K.M., Harikesh P.C.*, Bruno A., Jamaludin N.F.**, Lie S., Mathews N., and Dang C. (2019) Improved photovoltaic performance of triple-cation mixed-halide perovskite solar cells with binary trivalent metals incorporated into the titanium dioxide electron transport layer. Journal of Materials Chemistry C, 7, 17, 5028-5036. [IF: 6.4] ^##
• Yantara N.**, Jamaludin N.F.**, Febriansyah B., Bruno A., Tay Y.B., Mhaisalkar S., and Mathews N.~^ (2019) Regulating Vertical Domain Distribution in Ruddlesden-Popper Perovskites for Electroluminescence Devices. Journal of Physical Chemistry Letters, 10, 24, 7949-7955. [IF: 5.7] ^##
• Shini F., Thambidurai M., Harikesh P.C.*, Mathews N., Huang Y., and Dang C. (2019) Heterogeneous electron transporting layer for reproducible, efficient and stable planar perovskite solar cells. Journal of Power Sources, 437, 226907. [IF: 9.2] ^##
• Brown A.A.M., Hooper T.J.N., Veldhuis S.A., Chin X.Y., Bruno A., Vashishtha P., Tey J.N., Jiang L., Damodaran B., Pu S.H., Mhaisalkar S.G., and Mathews N.^ (2019) Self-assembly of a robust hydrogen-bonded octylphosphonate network on cesium lead bromide perovskite nanocrystals for light-emitting diode. Nanoscale, 11, 25, 12370-12380. [IF: 6.7] ^#
• Giovanni D., Lim J.W.M., Yuan Z., Lim S.S., Righetto M., Qing J., Zhang Q., Dewi H.A.**, Gao F., Mhaisalkar S.G., Mathews N., and Sum T.C. (2019) Ultrafast long-range spin-funneling in solution-processed Ruddlesden–Popper halide perovskites. Nature Communications, 10, 1, 3456. [IF: 16.6] ^##
• Wu B., Yuan H., Xu Q., Steele J.A., Giovanni D., Puech P., Fu J., Ng Y.F.*, Jamaludin N.F.**, Solanki A., Mhaisalkar S., Mathews N., Roeffaers M.B.J., Gratzel M., Hofkens J., and Sum T.C. (2019) Author Correction: Indirect tail states formation by thermal-induced polar fluctuations in halide perovskites. Nature Communications, 10, 1, 1145. [IF: 16.6] ^##
• Wu B., Yuan H., Xu Q., Steele J.A., Giovanni D., Puech P., Fu J., Ng Y.F.*, Jamaludin N.F.**, Solanki A., Mhaisalkar S., Mathews N., Roeffaers M.B.J., Gratzel M., Hofkens J., and Sum T.C. (2019) Indirect tail states formation by thermal-induced polar fluctuations in halide perovskites. Nature Communications, 10, 1, 484. [IF: 16.6] ^##
• Lim S.S., Giovanni D., Zhang Q., Solanki A., Jamaludin N.F.**, Lim J.W., Mathews N., Mhaisalkar S., Pshenichnikov M.S., and Sum T.C. (2019) Hot carrier extraction in CH3NH3PbI3 unveiled by pump-push-probe spectroscopy. Science Advances, 5, 11. [IF: 13.6] ^##
• Kulkarni M.R.**, John R.A.**, Tiwari N.*, Nirmal A.**, Ng S.E.**, Nguyen A.C., and Mathews N.~^ (2019) Field-Driven Athermal Activation of Amorphous Metal Oxide Semiconductors for Flexible Programmable Logic Circuits and Neuromorphic Electronics. Small, 15, 27, 1901457. [IF: 13.3] ^##
• Kulkarni S.A., Mhaisalkar S.G., Mathews N.~, and Boix P.P.** (2019) Perovskite Nanoparticles: Synthesis, Properties, and Novel Applications in Photovoltaics and LEDs. Small Methods, 3, 1, 1800231. [IF: 12.4] ^##

2018

• Thambidurai M., Dewi H.A.**, Harikesh P.C.*, Foo S., Muhammed Salim K.M., Mathews N., and Dang C. (2018) Highly Efficient Perovskite Solar Cells with Ba(OH)2 Interface Modification of Mesoporous TiO2 Electron Transport Layer. ACS Applied Energy Materials, 1, 11, 5847-5852. [IF: 6.4] ^#
• Ghosh B.*, Wu B., Mulmudi H.K.**, Guet C., Weber K., Sum T.C., Mhaisalkar S., and Mathews N.^ (2018) Limitations of Cs₃Bi₂I₉ as Lead-Free Photovoltaic Absorber Materials. ACS Applied Materials and Interfaces, 10, 41, 35000-35007. [IF: 9.5] ^##
• Tiwari N.*, Rajput M.**, John R.A.**, Kulkarni M.R.**, Nguyen A.C.**, and Mathews N.~^ (2018) Indium Tungsten Oxide Thin Films for Flexible High-Performance Transistors and Neuromorphic Electronics. ACS Applied Materials and Interfaces, 10, 36, 30506-30513. [IF: 9.5] ^##
• Subbiah A.S.**, Mathews N., Mhaisalkar S., and Sarkar S.K. (2018) Novel Plasma-Assisted Low-Temperature-Processed SnO2 Thin Films for Efficient Flexible Perovskite Photovoltaics. ACS Energy Letters, 3, 7, 1482-1491. [IF: 22] ^##
• Gonzalez-Pedro V., Veldhuis S.A.**, Begum R.**, Banuls M.J., Bruno A.**, Mathews N.^, Mhaisalkar S., and Maquieira A. (2018) Recovery of Shallow Charge-Trapping Defects in CsPbX3 Nanocrystals through Specific Binding and Encapsulation with Amino-Functionalized Silanes. ACS Energy Letters, 3, 6, 1409-1414. [IF: 22] ^##
• Salim K.M.M.**, Koh T.M.**, Bahulayan D., Harikesh P.C.**, Jamaludin N.F.*, Febriansyah B., Bruno A.**, Mhaisalkar S., and Mathews N.~^ (2018) Extended absorption window and improved stability of cesium-based triple-cation perovskite solar cells passivated with perfluorinated organics. ACS Energy Letters, 3, 5, 1068-1076. [IF: 22] ^##
• Veldhuis S.A.**, Ng Y.F.*, Ahmad R., Bruno A.**, Jamaludin N.F.*, Damodaran B., Mathews N., and Mhaisalkar S.G. (2018) Crown Ethers Enable Room-Temperature Synthesis of CsPbBr3 Quantum Dots for Light-Emitting Diodes. ACS Energy Letters, 3, 3, 526-531. [IF: 22] ^##
• John R.A.*, Tiwari N.*, Yaoyi C., Ankit.*, Tiwari N., Kulkarni M., Nirmal A.**, Nguyen A.C.**, Basu A., and Mathews N.~^ (2018) Ultralow Power Dual-Gated Subthreshold Oxide Neuristors: An Enabler for Higher Order Neuronal Temporal Correlations. ACS Nano, 12, 11, 11263-11273. [IF: 17.1] ^##
• Ghosh B.*, Wu B., Guo X., Harikesh P.C.*, John R.A.*, Baikie T., Arramel, Wee A.T.S., Guet C., Sum T.C., Mhaisalkar S., and Mathews N.^ (2018) Superior Performance of Silver Bismuth Iodide Photovoltaics Fabricated via Dynamic Hot-Casting Method under Ambient Conditions. Advanced Energy Materials, 8, 33, 1802051. [IF: 27.8] ^##
• Rolston N., Printz A.D., Tracy J.M., Weerasinghe H.C., Vak D., Haur L.J.**, Priyadarshi A.**, Mathews N., Slotcavage D.J., McGehee M.D., Kalan R.E., Zielinski K., Grimm R.L., Tsai H., Nie W., Mohite A.D., Gholipour S., Saliba M., Gratzel M., and Dauskardt R.H. (2018) Effect of Cation Composition on the Mechanical Stability of Perovskite Solar Cells. Advanced Energy Materials, 8, 9, 1702116. [IF: 27.8] ^##
• John R.A.*, Yantara N.**, Ng Y.F.*, Narasimman G., Mosconi E., Meggiolaro D., Kulkarni M.R.*, Gopalakrishnan P.K., Nguyen C.A., De Angelis F., Mhaisalkar S.G., Basu A., and Mathews N.~^ (2018) Ionotronic halide perovskite drift-diffusive synapses for low-power neuromorphic computation. Advanced Materials, 30, 51, 1805454. [IF: 29.4] ^##
• Yantara N.**, Bruno A.**, Iqbal A., Jamaludin N.F., Soci C., Mhaisalkar S., and Mathews N.~^ (2018) Designing Efficient Energy Funneling Kinetics in Ruddlesden–Popper Perovskites for High-Performance Light-Emitting Diodes. Advanced Materials, 30, 33, 1800818. [IF: 29.4] ^##
• Harikesh P.C.*, Wu B., Ghosh B.*, John R.A.*, Lie S., Thirumal K.**, Wong L.H., Sum T.C., Mhaisalkar S., and Mathews N.~^ (2018) Doping and switchable photovoltaic effect in lead-free perovskites enabled by metal cation transmutation. Advanced Materials, 30, 34, 1802080. [IF: 29.4] ^##
• John R.A.*, Liu F., Chien N.A.**, Kulkarni M.R.*, Zhu C., Fu Q., Basu A., Liu Z., and Mathews N.~^ (2018) Synergistic Gating of Electro-Iono-Photoactive 2D Chalcogenide Neuristors: Coexistence of Hebbian and Homeostatic Synaptic Metaplasticity. Advanced Materials, 30, 25, 1800220. [IF: 29.4] ^##
• Li M., Wei Q., Muduli S.K.**, Yantara N.**, Xu Q., Mathews N., Mhaisalkar S.G., Xing G., and Sum T.C. (2018) Enhanced Exciton and Photon Confinement in Ruddlesden–Popper Perovskite Microplatelets for Highly Stable Low-Threshold Polarized Lasing. Advanced Materials, 30, 23, 1707235. [IF: 29.4] ^##
• Giovanni D.*, Chong W.K., Liu Y.Y.F., Dewi H.A.**, Yin T., Lekina Y., Shen Z.X., Mathews N., Gan C.K., and Sum T.C. (2018) Coherent Spin and Quasiparticle Dynamics in Solution-Processed Layered 2D Lead Halide Perovskites. Advanced Science, 5, 10, 1800664. [IF:15.1] ^##
• Jamaludin N.F.*, Yantara N.**, Ng Y.F.*, Li M., Goh T.W., Thirumal K.*, Sum T.C., Mathews N., Soci C., and Mhaisalkar S. (2018) Grain Size Modulation and Interfacial Engineering of CH3NH3PbBr3 Emitter Films through Incorporation of Tetraethylammonium Bromide. ChemPhysChem, 19, 9, 1075-1080. [IF:2.9] ^#
• Bhaumik S.**, Veldhuis S.A.**, Muduli S.K.**, Li M., Begum R.**, Sum T.C., Mhaisalkar S., and Mathews N.~^ (2018) Inducing Isotropic Growth in Multidimensional Cesium Lead Halide Perovskite Nanocrystals. ChemPlusChem, 83, 6, 514-520. [IF: 2.9] ^#
• Hettiarachchi C., Birowosuto M.D., Nguyen T.H., Ahmad R., Pita K., Mathews N., and Dang C. (2018) Solution grown double heterostructure on a large hybrid halide perovskite crystal. CrystEngComm, 20, 42, 6653-6661. [IF: 3.1] ^#
• Kulkarni S.A., Han G.**, Tan K.S., Mhaisalkar S.G., and Mathews N.~^ (2018) Carrier cascade: Enabling high performance perovskite light-emitting diodes (PeLEDs). Current Opinion in Electrochemistry, 11, 91-97. [IF: 8.5]
• Chin X.Y.**, Perumal A.**, Bruno A.**, Yantara N.**, Veldhuis S.A.**, Martinez-Sarti L., Chandran B., Chirvony V., Lo A.S.-Z., So J., Soci C., Gratzel M., Bolink H.J., Mathews N.~^, and Mhaisalkar S.G. (2018) Self-assembled hierarchical nanostructured perovskites enable highly efficient LEDs: Via an energy cascade. Energy and Environmental Science, 11, 7, 1770-1778. [IF: 32.5] ^##
• Tiwari N.*, Ho F., Ankit.*, and Mathews N.~^ (2018) A rapid low temperature self-healable polymeric composite for flexible electronic devices. Journal of Materials Chemistry A, 6, 43, 21428-21434. [IF: 11.9] ^##
• Koh T.M.**, Shanmugam V., Guo X., Lim S.S., Filonik O., Herzig E.M., Muller-Buschbaum P., Swamy V., Chien S.T., Mhaisalkar S.G., and Mathews N.~^ (2018) Enhancing moisture tolerance in efficient hybrid 3D/2D perovskite photovoltaics. Journal of Materials Chemistry A, 6, 5, 2122-2128. [IF: 11.9] ^##
• Jamaludin N.F.*, Yantara N.**, Ng Y.F.*, Bruno A.*, Chandran B.K., Chin X.Y.**, Thirumal K., Mathews N., Soci C., and Mhaisalkar S. (2018) Perovskite templating: Via a bathophenanthroline additive for efficient light-emitting devices. Journal of Materials Chemistry C, 6, 9, 2295-2302. [IF: 6.4] ^##
• Han G.**, Hadi H.D., Bruno A.**, Kulkarni S.A.**, Koh T.M.**, Wong L.H., Soci C., Mathews N.~^, Zhang S., and Mhaisalkar S.G. (2018) Additive Selection Strategy for High Performance Perovskite Photovoltaics. Journal of Physical Chemistry C, 112, 25, 13884-13893. [IF: 3.7] ^#
• Walukiewicz W., Rey-Stolle I., Han G.**, Jaquez M., Broberg D., Xie W., Sherburne M., Mathews N., and Asta M. (2018) Bistable Amphoteric Native Defect Model of Perovskite Photovoltaics. Journal of Physical Chemistry Letters, 9, 14, 3878-3885. [IF: 5.7] ^##
• Bashir A.*, Shukla S.**, Lew J.H.**, Shukla S.**, Bruno A.**, Gupta D., Baikie T., Patidar R., Akhter Z., Priyadarshi A.**, Mathews N.~, and Mhaisalkar S.G. (2018) Spinel Co3O4 nanomaterials for efficient and stable large area carbon-based printed perovskite solar cells. Nanoscale, 10, 5, 2341-2350. [IF: 6.7] ^#
• Li M., Begum R.**, Fu J., Xu Q., Koh T.M.**, Veldhuis S.A., Gratzel M., Mathews N., Mhaisalkar S., and Sum T.C. (2018) Low threshold and efficient multiple exciton generation in halide perovskite nanocrystals. Nature Communications, 9, 1, 4197. [IF: 16.6] ^##
• Pham T.T.T.**, Mathews N., Lam Y.-M., and Mhaisalkar S. (2018) Influence of size and shape of sub-micrometer light scattering centers in ZnO-assisted TiO2 photoanode for dye-sensitized solar cells. Physica B: Condensed Matter, 532, 225-229. [IF: 2.8]
• Han G.**, Du W.H.*, An B.-L., Bruno A.**, Leow S.W., Soci C., Zhang S., Mhaisalkar S.G., and Mathews N.~^ (2018) Nitrogen doped cuprous oxide as low cost hole-transporting material for perovskite solar cells. Scripta Materialia, 153, 104-108. [IF: 6] ^#
• Ankit.*, Tiwari N.*, Rajput M.**, Chien N.A.**, and Mathews N.~^ (2018) Highly Transparent and Integrable Surface Texture Change Device for Localized Tactile Feedback. Small, 14, 1, 1702312. [IF: 13.3] ^##
• Liang C., Li P., Gu H., Zhang Y., Li F., Song Y., Shao G., Mathews N., and Xing G. (2018) One-Step Inkjet Printed Perovskite in Air for Efficient Light Harvesting. Solar RRL, 2, 2, 1700217. [IF: 7.9]

2017

• Koh T.M.**, Huang J.**, Neogi I.**, Boix P.P.**, Mhaisalkar S.G., and Mathews N.~^ (2017) High Stability Bilayered Perovskites through Crystallization Driven Self-Assembly. ACS Applied Materials and Interfaces, 9, 34, 28743-28749. [IF: 9.5] ^##
• Han G.**, Koh T.M.**, Lim S.S., Goh T.W., Guo X., Leow S.W., Begum R., Sum T.C., Mathews N.~^, and Mhaisalkar S. (2017) Facile Method to Reduce Surface Defects and Trap Densities in Perovskite Photovoltaics. ACS Applied Materials and Interfaces, 9, 25, 21292-21297. [IF: 9.5] ^##
• Kulkarni M.R.*, John R.A.*, Rajput M.**, Tiwari N.*, Yantara N.**, Nguyen A.C.**, and Mathews N.~^ (2017) Transparent Flexible Multifunctional Nanostructured Architectures for Non-optical Readout, Proximity, and Pressure Sensing. ACS Applied Materials and Interfaces, 9, 17, 15015- 15021. [IF: 9.5] ^##
• Guchhait A.*, Dewi H.A.**, Leow S.W., Wang H.**, Han G.**, Suhaimi F.B., Mhaisalkar S., Wong L.H., and Mathews N.~^ (2017) Over 20% Efficient CIGS-Perovskite Tandem Solar Cells. ACS Energy Letters, 2, 4, 807-812. [IF: 22] ^##
• Chakraborty S., Xie W., Mathews N., Sherburne M., Ahuja R., Asta M., and  Mhaisalkar S.G. (2017) Rational Design: A High-Throughput Computational Screening and Experimental Validation Methodology for Lead-Free and Emergent Hybrid Perovskites. ACS Energy Letters, 2, 4, 837-845. [IF: 22] ^##
• Ng Y.F.*, Jamaludin N.F.*, Yantara N.**, Li M., Irukuvarjula V.K.R., Demir H.V., Sum T.C., Mhaisalkar S., and Mathews N.~^ (2017) Rapid Crystallization of All-Inorganic CsPbBr3 Perovskite for High-Brightness Light-Emitting Diodes. ACS Omega, 2, 6, 2757-2764. [IF: 4.1] ^#
• Koh T.M.**, Febriansyah B., and Mathews N.~^ (2017) Ruddlesden-Popper Perovskite Solar Cells. Chem, 2, 3, 326-327. [IF: 23.5] ^##
• Ng Y.F.*, Kulkarni S.A.**, Parida S., Jamaludin N.F.*, Yantara N.**, Bruno A.**, Soci C., Mhaisalkar S., and Mathews N.~^ (2017) Highly efficient Cs-based perovskite light-emitting diodes enabled by energy funnelling. Chemical communications, 53, 88, 12004-12007. [IF: 4.9] ^##
• Cai Y., Xie W., Ding H., Chen Y., Thirumal K.**, Wong L.H., Mathews N., Mhaisalkar S.G., Sherburne M., and Asta M. (2017) Computational Study of Halide Perovskite-Derived A2BX6 Inorganic Compounds: Chemical Trends in Electronic Structure and Structural Stability. Chemistry of Materials, 29, 18, 7740-7749. [IF: 8.6] ^##
• Thirumal K.**, Chong W.K., Xie W., Ganguly R., Muduli S.K.**, Sherburne M., Asta M., Mhaisalkar S., Sum T.C., Soo H.S., and Mathews N.~^ (2017) Morphology-Independent Stable White-Light Emission from Self-Assembled Two-Dimensional Perovskites Driven by Strong Exciton-Phonon Coupling to the Organic Framework. Chemistry of Materials, 29, 9, 3947-3953. [IF: 8.6] ^##
• Shukla S.**, Shukla S.**, Haur L.J.**, Dintakurti S.S.H., Han G.**, Priyadarshi A.**, Baikie T., Mhaisalkar S.G., and Mathews N.~^ (2017) Effect of Formamidinium/Cesium Substitution and PbI2 on the Long-Term Stability of Triple-Cation Perovskites. ChemSusChem, 10, 9, 3804-3809. [IF: 8.4] ^##
• Kulkarni S.A.**, Muduli S.**, Xing G., Yantara N.**, Li M., Chen S., Sum T.C., Mathews N.~^, White T.J., and Mhaisalkar S.G. (2017) Modulating Excitonic Recombination Effects through One-Step Synthesis of Perovskite Nanoparticles for Light-Emitting Diodes. ChemSusChem, 10, 19, 3818- 3824. [IF: 8.4] ^##
• Neogi I.**, Bruno A.**, Bahulayan D.**, Goh T.W., Ghosh B.*, Ganguly R., Cortecchia D., Sum T.C., Soci C., Mathews N.~^, and Mhaisalkar S.G. (2017) Broadband-Emitting 2 D Hybrid Organic–Inorganic Perovskite Based on Cyclohexane-bis(methylamonium) Cation. ChemSusChem, 10, 19, 3765-3772. [IF: 8.4] ^##
• Gurudayal.*, John R.A.*, Boix P.P.**, Yi C., Shi C., Scott M.C., Veldhuis S.A.**, Minor A.M., Zakeeruddin S.M., Wong L.H., Gratzel M., and Mathews N.~^ (2017) Atomically Altered Hematite for Highly Efficient Perovskite Tandem Water-Splitting Devices. ChemSusChem, 10, 11, 2449-2456. [IF: 8.4] ^##
• Rai V.**, Tiwari N.*, Rajput M.**, Joshi S.M.**, Nguyen A.C.**, and Mathews N.~^ (2017) Reversible Electrochemical Silver Deposition over Large Areas for Smart Windows and Information Display. Electrochimica Acta, 255, 63-71. [IF: 6.6] ^#
• Ng Y.F.*, Neo W.J., Jamaludin N.F.*, Yantara N.**, Mhaisalkar S., and Mathews N.~^ (2017) Enhanced Coverage of All-Inorganic Perovskite CsPbBr3 through Sequential Deposition for Green Light-Emitting Diodes. Energy Technology, 5, 10, 1859-1865. [IF: 3.8]
• Kapoor V., Bashir A.**, Haur L.J.**, Bruno A.**, Shukla S.**, Priyadarshi A**., Mathews N., and Mhaisalkar S. (2017) Effect of Excess PbI2 in Fully Printable Carbon-based Perovskite Solar Cells. Energy Technology, 5, 10, 1880-1886. [IF: 3.8]
• Priyadarshi A.**, Bashir A.*, Gunawan J.T., Haur L.J.**, Bruno A.**, Akhter Z., Mathews N.~^, and Mhaisalkar S.G. (2017) Simplified Architecture of a Fully Printable Perovskite Solar Cell Using a Thick Zirconia Layer. Energy Technology, 5, 10, 1866-1872. [IF: 3.8]
• Kulkarni S.A.**, Baikie T., Muduli S.**, Potter R., Chen S., Yanan F., Bishop P., Lim S.S., Sum T.C., Mathews N.~^, and White T.J. (2017) Investigating the feasibility of symmetric guanidinium based plumbate perovskites in prototype solar cell devices. Japanese Journal of Applied Physics, 56, 08MC05. [IF: 1.5]
• Pham T.T.T.**, Mathews N., Lam Y.-M., and Mhaisalkar S. (2017) Enhanced Efficiency of Dye-Sensitized Solar Cells with Mesoporous–Macroporous TiO2 Photoanode Obtained Using ZnO Template. Journal of Electronic Materials, 46, 3801-3807. [IF: 2.1]
• Muduli S.K.**, Varrla E., Xu Y., Kulkarni S.A.**, Katre A., Chakraborty S., Chen S., Sum T.C., Xu R., and Mathews N.~^ (2017) Evolution of hydrogen by few-layered black phosphorus under visible illumination. Journal of Materials Chemistry A, 5, 47, 24874-24879. [IF: 11.9] ^##
• Ghosh B.*, Chakraborty S., Wei H., Guet C., Li S., Mhaisalkar S., and Mathews N.~^ (2017) Poor Photovoltaic Performance of Cs3Bi2I9: An Insight through First-Principles Calculations. Journal of Physical Chemistry C, 121, 32, 17062-17067. [IF: 3.7] ^#
• Muduli S.K.**, Varrla E., Kulkarni S.A.**, Han G.**, Thirumal K.**, Lev O., Mhaisalkar S., and Mathews N.~^ (2017) 2D black phosphorous nanosheets as a hole transporting material in perovskite solar cells. Journal of Power Sources, 371, 156-161. [IF: 9.2] ^##
• Leow W.R., Ng W.K.H., Peng T., Liu X., Li B., Shi W., Lum Y., Wang X., Lang X., Li S., Mathews N., Ager J.W., Sum T.C., Hirao H., and Chen X. (2017) Al2O3 surface complexation for photocatalytic organic transformations. Journal of the American Chemical Society, 139, 1, 269-276. [IF: 15] ^##
• Veldhuis S.A.**, Tay Y.K.E., Bruno A.**, Dintakurti S.S.H., Bhaumik S.**, Muduli S.K.**, Li M., Mathews N., Sum T.C., and Mhaisalkar S.G. (2017) Benzyl Alcohol-Treated CH3NH3PbBr3 Nanocrystals Exhibiting High Luminescence, Stability, and Ultralow Amplified Spontaneous Emission Thresholds. Nano Letters, 17, 12, 7424-7432. [IF: 10.8] ^#
• Tiwari N.*, Ankit.*, Rajput M.**, Kulkarni M.R.*, John R.A.*, and Mathews N.~^ (2017) Healable and flexible transparent heaters. Nanoscale, 9, 39, 14990-14997. [IF: 6.7] ^#
• Chen W., Bhaumik S.**, Veldhuis S.A.**, Xing G., Xu Q., Gratzel M., Mhaisalkar S., Mathews N.^, and Sum T.C. (2017) Giant five-photon absorption from multidimensional core-shell halide perovskite colloidal nanocrystals. Nature Communications, 8, 15198. [IF: 16.6] ^##
• Li M., Bhaumik S.**, Goh T.W., Kumar M.S., Yantara N.**, Gratzel M., Mhaisalkar S., Mathews N.^, and Sum T.C. (2017) Slow cooling and highly efficient extraction of hot carriers in colloidal perovskite nanocrystals. Nature communications, 8, 14350. [IF: 16.6] ^##
• John R.A.*, Ko J., Kulkarni M.R.*, Tiwari N.*, Chien N.A.**, Ing N.G., Leong W.L., and Mathews N.^ (2017) Flexible Ionic-Electronic Hybrid Oxide Synaptic TFTs with Programmable Dynamic Plasticity for Brain-Inspired Neuromorphic Computing. Small, 13, 12, 1701193. [IF: 13.3] ^##

2016

• Sum T.C., Mathews N., Xing G., Lim S.S., Chong W.K., Giovanni D.*, and Dewi H.A.** (2016) Spectral Features and Charge Dynamics of Lead Halide Perovskites: Origins and Interpretations. Accounts of Chemical Research, 49, 2, 294-302. [IF: 18.3] ^##
• John R.A.*, Nguyen A.C.**, Chen Y., Shukla S.** , Chen S., and Mathews N.~^ (2016) Modulating Cationic Ratios for High-Performance Transparent Solution-Processed Electronics. ACS Applied Materials and Interfaces, 8, 2, 1139-1146. [IF: 9.5] ^##
• Chen S., Roh K., Lee J., Chong W.K., Lu Y., Mathews N., Sum T.C., and Nurmikko A. (2016) A Photonic Crystal Laser from Solution Based Organo-Lead Iodide Perovskite Thin Films. ACS Nano, 10, 4, 3959-3967. [IF: 17.1] ^##
• Shukla S.**, Xing G., Ge H., Prabhakar R.R., Mathew S., Su Z., Nalla V., Venkatesan T., Mathews N., Sritharan T., Sum T.C., and Xiong Q. (2016) Origin of Photocarrier Losses in Iron Pyrite (FeS2) Nanocubes. ACS Nano, 10, 4, 4431-4440. [IF: 17.1] ^##
• Wu B., Nguyen H.T., Ku Z., Han G.**, Giovanni D.*, Mathews N., Fan H.J., and Sum T.C. (2016)  Advanced Energy Materials, 6, 14, 1600551. [IF: 27.8] ^##
• Xing G., Kumar M.H.*, Chong W.K., Liu X., Cai Y., Ding H., Asta M., Gratzel M., Mhaisalkar S., Mathews N.^, and Sum T.C. (2016) Solution-Processed Tin-Based Perovskite for Near-Infrared Lasing. Advanced Materials, 28, 37, 8191-8196. [IF: 29.4] ^##
• Veldhuis S.A.**, Boix P.P.**, Yantara N.**, Li M., Sum T.C., Mathews N., and Mhaisalkar S.G. (2016) Perovskite Materials for Light-Emitting Diodes and Lasers. Advanced Materials, 28, 32, 6804-6834. [IF: 29.4] ^##
• Koh T.M.**, Shanmugam V., Schlipf J., Oesinghaus L., Muller-Buschbaum P., Ramakrishnan N., Swamy V., Mathews N.~^, Boix P.P.**, and Mhaisalkar S.G. (2016) Nanostructuring Mixed-Dimensional Perovskites: A Route Toward Tunable, Efficient Photovoltaics. Advanced Materials, 28, 19, 3653-3661. [IF: 29.4] ^##
• Leong W.L., Ooi Z.-E., Sabba D.**, Yi C., Zakeeruddin S.M., Graetzel M., Gordon J.M., Katz E.A., and Mathews N. (2016) Identifying Fundamental Limitations in Halide Perovskite Solar Cells. Advanced Materials, 28, 12, 2439-2445. [IF:29.4] ^##
• Gurudayal.**, Jeong D., Jin K., Ahn H.-Y., Boix P.P.**, Abdi F.F., Mathews N., Nam K.T., and Wong L.H. (2016) Highly Active MnO Catalysts Integrated onto Fe2O3 Nanorods for Efficient Water Splitting. Advanced Materials Interfaces, 3, 15, 1600176. [IF: 5.4] ^#
• Bhaumik S.**, Veldhuis S.A.**, Ng Y.F.*, Li M., Muduli S.K.**, Sum T.C., Damodaran B., Mhaisalkar S., and Mathews N.~^ (2016) Highly stable, luminescent core-shell type methylammonium-octylammonium lead bromide layered perovskite nanoparticles. Chemical Communications, 52, 44, 7118-7121. [IF: 4.9] ^##
• John R.A.*, Chien N.A.**, Shukla S.**, Tiwari N.*, Shi C., Ing N.G., and Mathews N.~^ (2016) Low-temperature chemical transformations for high-performance solution-processed oxide transistors. Chemistry of Materials, 28, 22, 8305-8313. [IF: 8.6] ^##
• Harikesh P.C.*, Mulmudi H.K.**, Ghosh B.*, Goh T.W., Teng Y.T.**, Thirumal K.**, Lockrey M., Weber K., Koh T.M.**, Li S., Mhaisalkar S., and Mathews N.~^ (2016) Rb as an Alternative Cation for Templating Inorganic Lead-Free Perovskites for Solution Processed Photovoltaics. Chemistry of Materials, 28, 20, 7496-7504. [IF: 8.6] ^##
• Koh T.M.**, Thirumal K.**, Soo H.S., and Mathews N.~^ (2016) Multidimensional Perovskites: A Mixed Cation Approach Towards Ambient Stable and Tunable Perovskite Photovoltaics. ChemSusChem, 9, 18, 2541-2558. [IF: 8.4] ^##
• Priyadarshi A.**, Haur L.J.**, Murray P., Fu D., Kulkarni S.**, Xing G., Sum T.C., Mathews N.~^, and Mhaisalkar S.G. (2016) A large area (70 cm2) monolithic perovskite solar module with a high efficiency and stability. Energy and Environmental Science, 9, 12, 3687-3692. [IF: 32.5] ^##
• Cortecchia D., Dewi H.A.**, Yin J., Bruno A.**, Chen S., Baikie T., Boix P.P.**, Gratzel M., Mhaisalkar S., Soci C., and Mathews N.^ (2016) Lead-Free MA2CuClxBr4-x Hybrid Perovskites. Inorganic Chemistry, 55, 3, 1044-1052. [IF: 4.6] ^##
• Li Z., Boix P.P.**, Xing G., Fu K.**, Kulkarni S.A.**, Batabyal S.K.**, Xu W., Cao A., Sum T.C., Mathews N., and Wong L.H. (2016) Carbon nanotubes as an efficient hole collector for high voltage methylammonium lead bromide perovskite solar cells. Nanoscale, 8, 12, 6352-6360. [IF: 6.7] ^#
• Fu K.**, Nelson C.T., Scott M.C., Minor A., Mathews N.~^, and Wong L.H. (2016) Influence of void-free perovskite capping layer on the charge recombination process in high performance CH3NH3PbI3 perovskite solar cells. Nanoscale, 8, 7, 4181-4193. [IF: 6.7] ^#
• Lim S.S., Chong W.K., Solanki A., Dewi H.A.**, Mhaisalkar S., Mathews N.^, and Sum T.C. (2016) Modulating carrier dynamics through perovskite film engineering. Physical Chemistry Chemical Physics, 18, 39, 27119-27123. [IF: 3.3] ^#
• Chong W.K., Thirumal K.**, Giovanni D.*, Goh T.W., Liu X., Mathews N., Mhaisalkar S., and Sum T.C. (2016) Dominant factors limiting the optical gain in layered two-dimensional halide perovskite thin films. Physical Chemistry Chemical Physics, 18, 21, 14701-14708. [IF: 3.3] ^#
• Giovanni D.*, Chong W.K., Dewi H.A.**, Thirumal K.**, Neogi I.**, Ramesh R., Mhaisalkar S., Mathews N.~^, and Sum T.C. (2016) Tunable room-temperature spin-selective optical Stark effect in solution-processed layered halide perovskites. Science Advances, 2, 6, 1600477. [IF: 13.6] ^##

2015

• Wu B., Fu K.**, Yantara N.**, Xing G., Sun S., Sum T.C., and Mathews N.^ (2015) Charge Accumulation and Hysteresis in Perovskite-Based Solar Cells: An Electro-Optical Analysis. Advanced Energy Materials, 5, 19, 1500829. [IF: 27.8] ^##
• Yantara N.**, Yanan F., Shi C., Dewi H.A.**, Boix P.P.**, Mhaisalkar S.G., and Mathews N.~^ (2015) Unravelling the Effects of Cl Addition in Single Step CH3NH3PbI3 Perovskite Solar Cells. Chemistry of Materials, 27, 7, 2309-2314. [IF: 8.6] ^##
• Koh T.M.**, Krishnamoorthy T.**, Yantara N.**, Shi C., Leong W.L., Boix P.P.**, Grimsdale A.C., Mhaisalkar S.G., and Mathews N.~^ (2015) Formamidinium tin-based perovskite with low Eg for photovoltaic applications. Journal of Materials Chemistry A, 3, 29, 14996-15000. [IF: 11.9] ^##
• Krishnamoorthy T.**, Ding H., Yan C., Leong W.L., Baikie T., Zhang Z., Sherburne M., Li S., Asta M., Mathews N.~^, and Mhaisalkar S.G. (2015) Lead-free germanium iodide perovskite materials for photovoltaic applications. Journal of Materials Chemistry A, 3, 47, 23829-23832. [IF: 11.9] ^##
• Sabba D.**, Mulmudi H.K.**, Prabhakar R.R.**, Krishnamoorthy T.**, Baikie T., Boix P.P.**, Mhaisalkar S., and Mathews N.~^ (2015) Impact of anionic Br- substitution on open circuit voltage in lead free perovskite (CsSnI3-xBrx) solar cells. Journal of Physical Chemistry C, 119, 4, 1763-1767. [IF: 3.7] ^#
• Yantara N.**, Bhaumik S.**, Yan F., Sabba D.**, Dewi H.A.**, Mathews N.~^, Boix P.P.**, Demir H.V., and Mhaisalkar S. (2015) Inorganic Halide Perovskites for Efficient Light-Emitting Diodes. Journal of Physical Chemistry Letters, 6, 21, 4360-4364. [IF: 5.7] ^##
• Yin J., Cortecchia D., Krishna A., Chen S., Mathews N., Grimsdale A.C., and Soci C. (2016) Interfacial charge transfer anisotropy in polycrystalline lead iodide perovskite films. Journal of Physical Chemistry Letters, 6, 8, 1396-1402. [IF: 5.7] ^##
• Boix P.P.**, Agarwala S.**, Koh T.M.**, Mathews N.~, and Mhaisalkar S.G. (2015) Perovskite solar cells: Beyond methylammonium lead iodide. Journal of Physical Chemistry Letters, 6, 5, 898-907. [IF: 5.7] ^##
• Gurudayal.**, Sabba D.**, Kumar M.H.**, Wong L.H., Barber J., Gratzel M., and Mathews N.~^ (2015) Perovskite-Hematite Tandem Cells for Efficient Overall Solar Driven Water Splitting. Nano Letters, 15, 6, 3833-3839. [IF: 10.8] ^##
• Giovanni D.*, Ma H., Chua J**., Gratzel M., Ramesh R., Mhaisalkar S., Mathews N.^, and Sum T.C. (2015) Highly spin-polarized carrier dynamics and ultralarge photoinduced magnetization in CH3NH3PbI3 perovskite thin films. Nano Letters, 15, 3, 1553-1558. [IF: 10.8] ^##
• Yantara N.**, Pham T.T.T., Boix P.P.**, and Mathews N.~^ (2015)  Modulating light propagation in ZnO-Cu2O-inverse opal solar cells for enhanced photocurrents. Physical Chemistry Chemical Physics, 17, 33, 21694-21701. [IF: 3.3] ^#
• Xing G., Wu B., Chen S., Chua J.**, Yantara N.**, Mhaisalkar S., Mathews N.^, and Sum T.C. (2015) Interfacial Electron Transfer Barrier at Compact TiO2/CH3NH3PbI3 Heterojunction. Small, 11, 29, 3606-3613. [IF: 13.3] ^##

2014

• Chandra R.D., Rao M., Zhang K., Prabhakar R.R., Shi C., Zhang J., Mhaisalkar S.G., and Mathews N.^ (2014) Tuning electrical properties in amorphous zinc tin oxide thin films for solution processed electronics. ACS Applied Materials and Interfaces, 6, 2, 773-777. [IF: 9.5] ^##
• Shukla S.**, Loc N.H., Boix P.P.**, Koh T.M.**, Prabhakar R.R., Mulmudi H.K.**, Zhang J., Chen S., Ng C.F., Huan C.H.A., Mathews N., Sritharan T., and Xiong Q. (2014) Iron pyrite thin film counter electrodes for dye-sensitized solar cells: High efficiency for iodine and cobalt redox electrolyte cells. ACS Nano, 8, 10, 10597-10605. [IF: 17.1] ^##
• Liu X., Wu B., Zhang Q., Yip J.N., Yu G., Xiong Q., Mathews N.^, and Sum T.C. (2014) Elucidating the localized plasmonic enhancement effects from a single Ag nanowire in organic solar cells. ACS Nano, 8, 10, 10101-10110. [IF: 17.1] ^##
• Li Z.**, Kulkarni S.A.**, Boix P.P.**, Shi E., Cao A., Fu K.**, Batabyal S.K.**, Zhang J., Xiong Q., Wong L.H., Mathews N.~^, and Mhaisalkar S.G. (2014) Laminated carbon nanotube networks for metal electrode-free efficient perovskite solar cells. ACS Nano, 8, 7, 6797-6804. [IF: 17.1] ^##
• Kumar M.H.**, Dharani S.**, Leong W.L., Boix P.P.**, Prabhakar R.R.**, Baikie T., Shi C., Ding H., Ramesh R., Asta M., Graetzel M., Mhaisalkar S.G., and Mathews N.~^ (2014) Lead-free halide perovskite solar cells with high photocurrents realized through vacancy modulation. Advanced Materials, 26, 41, 7122-7127. [IF: 29.4] ^##
• Chen S., Goh T.W., Sabba D.*, Chua J.*, Mathews N., Huan C.H.A., and Sum T.C. (2014) Energy level alignment at the methylammonium lead iodide/copper phthalocyanine interface. APL Materials, 2, 8, 081512. [IF: 6.1] ^#
• Wei C., Yu L., Cui C., Lin J., Wei C., Mathews N., Huo F., Sritharan T., and Xu Z. (2014) Ultrathin MnO2 nanoflakes as efficient catalysts for oxygen reduction reaction. Chemical Communicatrions, 50, 58, 7885-7888. [IF: 4.9] ^##
• Wang V.B.**, Yantara N.**, Koh T.M.**, Kjelleberg S., Zhang Q., Bazan G.C., Chye Joachim Loo S., and Mathews N.~^ (2014) Uncovering alternate charge transfer mechanisms in escherichia coli chemically functionalized with conjugated oligoelectrolytes. Chemical Communications, 50, 60, 8223-8226. [IF: 4.9] ^##
• Trang Pham T.T.**, Koh T.M.**, Nonomura K., Lam Y.M., Mathews N.^, and Mhaisalkar S. (2014) Reducing mass-transport limitations in cobalt-electrolyte-based dye-sensitized solar cells by photoanode modification. ChemPhysChem, 15, 16, 1216-1221. [IF: 2.9] ^#
• Koh T.M.**, Dharani S.**, Li H., Prabhakar R.R.**, Mathews N.~^, Grimsdale A.C., and Mhaisalkar S.G. ( 2014) Cobalt dopant with deep redox potential for organometal halide hybrid solar cells. ChemSusChem, 7, 7, 1909-1914. [IF: 8.4] ^##
• Sum T.C., and Mathews N.^ (2014) Advancements in perovskite solar cells: Photophysics behind the photovoltaics. Energy and Environmental Science, 7, 8, 2518-2534. [IF: 32.5] ^##
• Sun S., Salim T., Mathews N., Duchamp M., Boothroyd C., Xing G., Sum T.C., and Lam Y.M. (2014) The origin of high efficiency in low-temperature solution-processable bilayer organometal halide hybrid solar cells. Energy and Environmental Science, 7, 1, 399-407. [IF: 32.5] ^##
• Kulkarni S.A.**, Baikie T., Boix P.P.**, Yantara N.**, Mathews N.~^, and Mhaisalkar S. (2014) Band-gap tuning of lead halide perovskites using a sequential deposition process. Journal of Materials Chemistry A, 2, 24, 9221-9225. [IF: 11.9] ^##
• Krishnamoorthy T.**, Kunwu F., Boix P.P.**, Li H., Koh T.M., Leong W.L., Powar S.**, Grimsdale A., Gratzel M., Mathews N.~^, and Mhaisalkar S.G. (2014) A swivel-cruciform thiophene based hole-transporting material for efficient perovskite solar cells. Journal of Materials Chemistry A, 2, 18, 6305-6309. [IF: 11.9] ^##
• Sun C.*, Karthik K.R.G.**, Pramana S.S., Wong L.H., Zhang J., Yizhong H., Sow C.H., Mathews N.^, and Mhaisalkar S.G.(2014) The role of tin oxide surface defects in determining nanonet FET response to humidity and photoexcitation. Journal of Materials Chemistry C, 2, 5, 940-945. [IF: 6.4] ^##
• Koh T.M.**, Fu K.**, Fang Y., Chen S., Sum T.C., Mathews N.~, Mhaisalkar S.G., Boix P.P.**, and  Baikie T. (2014) Formamidinium-containing metal-halide: An alternative material for near-IR absorption perovskite solar cells. Journal of Physical Chemistry C, 118, 30, 16458-16462. [IF: 3.7] ^#
• Dotan H., Mathews N., Hisatomi T., Gratzel M., and Rothschild A. (2014) On the solar to hydrogen conversion efficiency of photoelectrodes for water splitting. Journal of Physical Chemistry Letters, 5, 19, 3330-3334. [IF: 5.7] ^##
• Boix P.P.**, Nonomura K., Mathews N.~^, Mhaisalkar S.G. (2014) Current progress and future perspectives for organic/inorganic perovskite solar cells. Materials Today, 17, 1, 16-23. [IF: 24.2] ^##
• Fu K.**, Lim S.S., Fang Y., Boix P.P.**, Mathews N., Sum T.C., Wong L.H., and Mhaisalkar S. (2014) Modulating CH3NH3PbI3 perovskite crystallization behavior through precursor concentration. Nano, 9, 5, 1440003. [IF: 1.2]
• Dharani S.**, Dewi H.A.**, Prabhakar R.R.**, Baikie T., Shi C., Yonghua D., Mathews N., Boix P.P.**, and Mhaisalkar S.G. (2014) Incorporation of Cl into sequentially deposited lead halide perovskite films for highly efficient mesoporous solar cells. Nanoscale, 6, 22, 13854-13860. [IF: 6.7] ^#
• Dharani S.**, Mulmudi H.K.**, Yantara N.**, Thu Trang P.T., Park N.G., Graetzel M., Mhaisalkar S., Mathews N.~^, and Boix P.P.** (2014) High efficiency electrospun TiO2 nanofiber based hybrid organic-inorganic perovskite solar cell. Nanoscale, 6, 3, 1675-1679. [IF: 6.7] ^#
• Xing G., Mathews N.^, Lim S.S., Yantara N.**, Liu X., Sabba D.**, Gratzel M., Mhaisalkar S., and Sum T.C. (2014) Low-temperature solution-processed wavelength-tunable perovskites for lasing. Nature Materials, 13, 476-480. [IF: 41.2] ^##
• Dr. Nripan Mathews contributed equally as 1^st Author with Xing G.
• Chong W.K., Xing G., Liu Y., Gui E.L.*, Zhang Q., Xiong Q., Mathews N., Gan C.K., and Sum T.C. (2014) Direct measurement of coherent phonon dynamics in solution-processed stibnite thin films. Physical Review B - Condensed Matter and Materials Physics, 90, 035208. [IF: 3.7] ^##

2013 and before

• Kumar M.H., Yantara N., Dharani S., Mhaisalkar S., Boix P.P., and Mathews N.^ (2013) Flexible, low-temperature, solution processed ZnO-based perovskite solid state solar cells. Chemical Communications, 49, 94, 11089-11091. [IF: 4.9] ^##
• Koh T.M., Li H., Nonomura K., Mathews N., Hagfeldt A., Gratzel M., Mhaisalkar S.G., and Grimsdale A.C. (2013) Photovoltage enhancement from cyanobiphenyl liquid crystals and 4-tert-butylpyridine in Co(II/III) mediated dye-sensitized solar cells. Chemical Communications, 49, 80,  9101-9103. [IF: 4.9] ^##
• Kumar M.H., Mathews N.^, Boix P.P., Nonomura K., Powar S.**, Lam Y.M., Graetzel M., and Mhaisalkar S.G. (2013) Decoupling light absorption and charge transport properties in near IR-sensitized Fe2O3 regenerative cells. Energy and Environmental Science, 6, 11, 3280-3285. [IF: 32.5] ^##
• Wang D., Kanhere P., Li M., Tay Q., Tang Y., Huang Y., Sum T.C., Mathews N., Sritharan T., and  Chen Z. (2013) Improving photocatalytic H2 evolution of TiO2 via formation of {001}-{010} quasi-heterojunctions. Journal of Physical Chemistry C, 117, 44, 22894-22902. [IF: 3.7] ^#
• Koh T.M., Nonomura K., Mathews N., Hagfeldt A., Gratzel M., Mhaisalkar S.G., and Grimsdale A.C. (2013) Influence of 4-tert-butylpyridine in DSCs with CoII/III redox mediator. Journal of Physical Chemistry C, 117, 30, 15515-15522. [IF: 3.7] ^#
• Li F., Jennings J.R., Wang Q., Chua J., Mathews N., Mhaisalkar S.G., Moon S.-J., Zakeeruddin S.M., and Gratzel M. (2013) Determining the conductivities of the two charge transport phases in solid-state dye-sensitized solar cells by impedance spectroscopy. Journal of Physical Chemistry C, 117, 21, 10980-10989. [IF: 3.7] ^#
• Nguyen M., Tran P.D., Pramana S.S., Lee R.L., Batabyal S.K.*, Mathews N., Wong L.H., and  Graetzel M. (2013) In situ photo-assisted deposition of MoS2 electrocatalyst onto zinc cadmium sulphide nanoparticle surfaces to construct an efficient photocatalyst for hydrogen generation. Nanoscale, 5, 4, 1479-1482. [IF: 6.7] ^#
• Wu B., Wu X., Guan C., Tai K.F., Yeow E.K.L., Fan H.J., Mathews N.^, and Sum T.C. (2013) Uncovering loss mechanisms in silver nanoparticle-blended plasmonic organic solar cells. Nature Communications, 4, 2004. [IF: 16.6] ^##
• Xing G., Mathews N.^, Sun S., Lim S.S., Lam Y.M., Gratzel M., Mhaisalkar S., and Sum T.C. (2013) Long-range balanced electron-and hole-transport lengths in organic-inorganic CH3NH3PbI3. Science, 342, 6156, 344-347. [IF: 56.9] ^##
• Dr Nripan Mathews contributed equally as 1^st Author with Xing G.
• Sabba D., Mathews N.^, Chua J., Pramana S.S., Mulmudi H.K., Wang Q., and Mhaisalkar S.G. (2013) High-surface-area, interconnected, nanofibrillar TiO2 structures as photoanodes in dye-sensitized solar cells. Scripta Materialia, 68, 7, 487-490. [IF: 6] ^#
• Tjoa V., Chua J., Pramana S.S., Wei J., Mhaisalkar S.G., and Mathews N.^ (2012) Facile photochemical synthesis of graphene-Pt nanoparticle composite for counter electrode in dye sensitized solar cell. ACS Applied Materials and Interfaces, 4, 7, 3447-3452. [IF: 9.5] ^##
• Khaderbad M.A., Tjoa V., Rao M., Phandripande R., Madhu S., Wei J., Ravikanth M., Mathews N.^, Mhaisalkar S.G., and Rao V.R. (2012) Fabrication of unipolar graphene field-effect transistors by modifying source and drain electrode interfaces with zinc porphyrin. ACS Applied Materials and Interfaces, 4, 3, 1434-1439. [IF: 9.5] ^##
• Hisatomi T., Dotan H., Stefik M., Sivula K., Rothschild A., Gratzel M., and Mathews N.^ (2012) Enhancement in the performance of ultrathin hematite photoanode for water splitting by an oxide underlayer. Advanced Materials, 24, 20, 2699-2702. [IF: 29.4] ^##
• Yantara N., Mathews N.^, Jinesh K.B., Mulmudi H.K., and Mhaisalkar S.G. ( 2012) Modulating the optical and electrical properties of all metal oxide solar cells through nanostructuring and ultrathin interfacial layers. Electrochimica Acta, 85, 486-491. [IF: 6.6] ^#
• Paracchino A., Mathews N.^, Hisatomi T., Stefik M., Tilley S.D., and Gratzel M. (2012) Ultrathin films on copper(i) oxide water splitting photocathodes: A study on performance and stability. Energy and Environmental Science, 5, 9, 8673-8681. [IF: 32.5] ^##
• Mukherjee B., Varghese B., Zheng M., Karthik K.R.G., Mathews N., Mhaisalkar S.G., Tok E.S., and Sow C.H. (2012) Synthesis, characterization and electrical properties of hybrid Zn 2GeO 4-ZnO beaded nanowire arrays. Journal of Crystal Growth, 346, 1, 32-39. [IF: 1.8] ^#
• Trang Pham T.T., Bessho T., Mathews N.^, Zakeeruddin S.M., Lam Y.M., Mhaisalkar S., and Gratzel M. (2012) Light scattering enhancement from sub-micrometer cavities in the photoanode for dye-sensitized solar cells. Journal of Materials Chemistry, 22, 32, 16201-16204. [IF: N/A]
• Hossain M.A., Jennings J.R., Shen C., Pan J.H., Koh Z.Y., Mathews N., and Wang Q. (2012) CdSe-sensitized mesoscopic TiO2 solar cells exhibiting >5% efficiency: redundancy of CdS buffer layer. Journal of Materials Chemistry, 22, 32, 16235-16242. [IF: N/A]
• Prabhakar R.R., Mathews N.^, Jinesh K.B., Karthik K.R.G., Pramana S.S., Varghese B., Sow C.H., and Mhaisalkar S. (2012) Efficient multispectral photodetection using Mn doped ZnO nanowires. Journal of Materials Chemistry, 22, 19, 9678-9683. [IF: N/A]
• Lu J., Sun C., Zheng M., Wang Y., Mathews N., Van Kan J.A., Mhaisalkar S.G., and Sow C.H. (2012) Ultrasensitive phototransistor based on K-enriched MoO 3 single nanowires. Journal of Physical Chemistry C, 116, 41, 22015-22020. [IF: 3.7] ^#
• Wu B., Oo T.Z., Li X., Liu X., Wu X., Yeow E.K.L., Fan H.J., Mathews N. and  Sum T.C. (2012) Efficiency enhancement in bulk-heterojunction solar cells integrated with large-area Ag nanotriangle arrays. Journal of Physical Chemistry C, 116, 28, 14820-14825. [IF: 3.7] ^#
• Oo T.Z., Mathews N.^, Xing G., Wu B., Xing B., Wong L.H., Sum T.C., and Mhaisalkar S.G. (2012) Ultrafine gold nanowire networks as plasmonic antennae in organic photovoltaics. Journal of Physical Chemistry C, 116, 10, 6453-6458. [IF: 3.7] ^#
• Dou X., Prabhakar R.R., Mathews N., Lam Y.M., and Mhaisalkar S. (2012) Zn-doped SnO2 nanocrystals as efficient DSSC photoanode material and remarkable photocurrent enhancement by interface modification. Journal of the Electrochemical Society, 159, 9, H735-H739. [IF: 3.9] ^#
• Gui E.L., Kang A.M., Pramana S.S., Yantara N., Mathews N.^, and Mhaisalkar S. (2012) Effect of TiO 2 mesoporous layer and surface treatments in determining efficiencies in antimony sulfide-(Sb 2S 3) sensitized solar cells. Journal of the Electrochemical Society, 159, 3, B247-B250. [IF: 3.9] ^#
• Stefik M., Cornuz M., Mathews N., Hisatomi T., Mhaisalkar S., and Gratzel M. (2012) Transparent, conducting Nb:SnO 2 for host-guest photoelectrochemistry. Nano Letters. 12, 10, 5431-5435. [IF: 10.8] ^##
• Lu J., Liu H., Sun C., Zheng M.,Mathews N., Chen G.S.,  Mhaisalkar S.G., Zhang X., and Sow C.H. (2012) Optical and electrical applications of ZnS xSe 1-x nanowires-network with uniform and controllable stoichiometry. Nanoscale. 4, 3, 976-981.[IF: 6.7] ^#
• Fu K., Sun C., Mathews N., and Mhaisalkar S.G. (2012) Dye-sensitized solar cells based on tin oxide nanowire network. Nanoscience and Nanotechnology Letters, 4, 7, 733-737. [IF: 1.128]
• Boxi X., Kumar M.H., Prabhakar R.R., Mathews N.^, and Mhaisalkar S.G. (2012) The effect of annealing temperature on the optical properties of In2S3 thin film. Nanoscience and Nanotechnology Letters, 4, 7, 747-749. [IF: 1.128]
• Tjoa V., Mathews N., Wei J., and Mhaisalkar S. (2012) Imparting photosensitivity through decoration of nanoparticle on reduced graphene oxide. Nanoscience and Nanotechnology Letters, 4, 7, 738-742. [IF: 1.128]
• Khaderbad M.A., Tjoa V., Mathews N., Madhu S., Ravikanth M., and Rao V.R. (2012) Modification of electronic properties of graphene with porphyrin self-assembled monolayers and photoinduced interactions. Nanoscience and Nanotechnology Letters, 4, 743-746. [IF: 1.128]
• Oo T.Z., Devi Chandra R., Yantara N., Prabhakar R.R., Wong L.H., Mathews N.^, and Mhaisalkar S.G. (2012) Zinc Tin Oxide (ZTO) electron transporting buffer layer in inverted organic solar cell. Organic Electronics, 13, 5, 870-874. [IF: 3.2] ^#
• Hossain M.A., Jennings J.R., Mathews N., and Wang Q. (2012) Band engineered ternary solid solution CdS xSe 1-x-sensitized mesoscopic TiO 2 solar cells. Physical Chemistry Chemical Physics, 14, 19, 7154-7161. [IF: 3.3] ^#
• Wu B., Liu X., Oo T.Z., Xing G., Mathews N., and Sum T.C. (2012) Resonant Aluminum Nanodisk Array for Enhanced Tunable Broadband Light Trapping in Ultrathin Bulk Heterojunction Organic Photovoltaic Devices. Plasmonics, 7, 677-684. [IF: 3]
• Liu H., Cheng S., Junpeng L., Minrui Z., Yong L.K., Mathews N., Mhaisalkar S.G., Hai T.S., Xinhai Z., and Haur S.C. (2012) Improved electrical property of Sb-doped SnO 2 nanonets as measured by contact and non-contact approaches. RSC Advances, 2, 25, 9590-9595. [IF: 3.9] ^#
• Khaderbad M.A., Tjoa V., Oo T.Z., Wei J., Sheri M., Mangalampalli R., Rao V.R., Mhaisalkar S.G., and Mathews N.^ (2012) Facile fabrication of graphene devices through metalloporphyrin induced photocatalytic reduction. RSC Advances, 2, 10, 4120-4124. [IF: 3.9] ^#
• Karthik K.R.G., Mulmudi H.K., Jinesh K.B., Mathews N., Sow C.H., Huang Y.Z., and Mhaisalkar S.G. (2011) Charge transport in hierarchical α-Fe2O3 nanostructures. Applied Physics Letters, 99, 13, 132105. [IF: 4.0] ^##
• Dou X., Sabba D., Mathews N., Wong L.H., Lam Y.M., and Mhaisalkar S. (2011) Hydrothermal synthesis of high electron mobility Zn-doped SnO2 nanoflowers as photoanode material for efficient dye-sensitized solar cells. Chemistry of Materials, 23, 17, 3938-3945. [IF: 8.6] ^##
• Karthik K.R.G., Andreasson B.P., Sun C., Pramana S.S., Varghese B., Sow C.H., Mathews N.^, Wong L.H., and Mhaisalkar S.G. (2011) Physical and electrical properties of single Zn2 Sn O 4 nanowires. Electrochemical and Solid-State Letters, 14, 1, K5-K7. [IF: 2.321]
• Mulmudi H.K., Mathews N.^, Dou X.C., Xi L.F., Pramana S.S., Lam Y.M., and Mhaisalkar S.G. (2011). Controlled growth of hematite (α-Fe2O3) nanorod array on fluorine doped tin oxide: Synthesis and photoelectrochemical properties. Electrochemistry Communications, 13, 9, 951-954. [IF: 5.4] ^#
• Tjoa V., Jun W., Dravid V., Mhaisalkar S., and Mathews N.^ (2011) Hybrid graphene-metal nanoparticle systems: Electronic properties and gas interaction. Journal of Materials Chemistry, 21, 39, 15593-15599. [IF: N/A]
• Leong W.L., Mathews N.^, Tan B., Vaidyanathan S., Dotz F., and Mhaisalkar S. (2011) Solution processed non-volatile top-gate polymer field-effect transistors. Journal of Materials Chemistry, 21, 25, 8971-8974. [IF: N/A]
• Leong W.L., Mathews N.^, Tan B., Vaidyanathan S., Dotz F., and Mhaisalkar S. (2011) Towards printable organic thin film transistor based flash memory devices. Journal of Materials Chemistry, 21, 14, 5203-5214. [IF: N/A]
• Zeng X., Xu X., Shenai P.M., Kovalev E., Baudot C., Mathews N., and Zhao Y. (2011) Characteristics of the electrical percolation in carbon nanotubes/polymer nanocomposites. Journal of Physical Chemistry C, 115, 44, 21685-21690. [IF: 3.7] ^#
• Junpeng L., Cheng S., Minrui Z., Mathews N., Hongwei L., Gin Seng C., Xinhai Z., Mhaisalkar S.G., and Chorng Haur S. (2011) Facile one-step synthesis of CdSxSe1- x nanobelts with uniform and controllable stoichiometry. Journal of Physical Chemistry C, 115, 40, 19538-19545. [IF: 3.7] ^#
• Li F., Jennings J.R., Mathews N., and Wang Q. (2011) Evolution of charge collection / separation efficiencies in dye-sensitized solar cells upon aging: A case study. Journal of the Electrochemical Society, 158, 9, B1158-B1163. [IF: 3.9] ^#
• Dou X., Li H., Mathews N., Helena Wong L., Lam Y.M., and Mhaisalkar S. (2011) Cu-S nanocabbage films with tunable optical bandgap and substantially improved stability by pulse electrodeposition. Journal of the Electrochemical Society, 158, 6, E60-E62. [IF: 3.9] ^#
• Dou X., Mathews N., Wang Q., Pramana S.S., Lam Y.M., and Mhaisalkar S. (2011) Novel Zn-Sn-O nanocactus with excellent transport properties as photoanode material for high performance dye-sensitized solar cells. Nanoscale, 3, 11, 4640-4646. [IF: 6.7] ^#
• Chua J., Mathews N.^, Jennings J.R., Yang G., Wang Q., and Mhaisalkar S.G. (2011) Patterned 3-dimensional metal grid electrodes as alternative electron collectors in dye-sensitized solar cells. Physical Chemistry Chemical Physics, 13, 43, 19314-19317. [IF: 3.3] ^#
• Mulmudi H.K., Batabyal S.K., Rao M., Prabhakar R.R., Mathews N., Lam Y.M., and Mhaisalkar S.G. (2011) Solution processed transition metal sulfides: Application as counter electrodes in dye sensitized solar cells (DSCs). Physical Chemistry Chemical Physics, 13, 43, 19307-19309. [IF: 3.3] ^#
• Tan H.S., Wang B.C., Kamath S., Chua J., Shojaei-Baghini M., Rao V.R., Mathews N., and Mhaisalkar S.G. (2010) Complementary organic circuits using evaporated F16CuPc and inkjet printing of PQT. IEEE Electron Device Letters, 31, 11, 1311-1313. [IF: 4.9] ^#
• Mathews N., Lam Y.M., Mhaisalkar S.G., and Grimsdale A.C. (2010) Printing materials for electronic devices. International Journal of Materials Research, 101, 2, 236-250. [IF: 0.8]
• Sun C., Mathews N.^, Zheng M., Sow C.H., Wong L.H., and Mhaisalkar S.G. (2010) Aligned tin oxide nanonets for high-performance transistors. Journal of Physical Chemistry C, 114, 2, 1331-1336. [IF: 3.7] ^#
• Mathews N., Varghese B., Sun C., Thavasi V., Andreasson B.P., Sow C.H., Ramakrishna S., and Mhaisalkar S.G. (2010) Oxide nanowire networks and their electronic and optoelectronic characteristics. Nanoscale, 2, 10, 1984-1998. [IF: 6.7] ^#
• Ahmadi M., Phonthammachai N., Shuan T.H., White T.J., Mathews N.^, and Mhaisalkar S.G. (2010) Solution processable nanoparticles as high-k dielectric for organic field effect transistors. Organic Electronics, 11, 10, 1660-1667. [IF: 3.2] ^#
• Oo T.Z., Mathews N.^, Tam T.L., Xing G.C., Sum T.C., Sellinger A., Wong L.H., and Mhaisalkar S.G. (2010) Investigation of photophysical, morphological and photovoltaic behavior of poly(p-phenylene vinylene) based polymer/oligomer blends. Thin Solid Films, 518, 18, 5292-5299. [IF: N/A]
• Tan H.S., Mathews N.^, Cahyadi T., Zhu F.R., and Mhaisalkar S.G. (2009) The effect of dielectric constant on device mobilities of high-performance, flexible organic field effect transistors. Applied Physics Letters, 94, 26, 263303. [IF: 4.0] ^##
• Leong W.L., Mathews N., Mhaisalkar S., Lam Y.M., Chen T., and Lee P.S. (2009) Micellar poly(styrene-b-4-vinylpyridine)-nanoparticle hybrid system for non-volatile organic transistor memory. Journal of Materials Chemistry, 19, 39, 7354-7361. [IF: N/A]
• Leong W.L., Mathews N., Mhaisalkar S.G., Chen T.P., and Lee P.S. (2008) Charging dynamics of discrete gold nanoparticle arrays self-assembled within a poly(styrene- b-4-vinylpyridine) diblock copolymer template. Applied Physics Letters, 93, 22, 222908. [IF: 4.0] ^##
• Mathews N.^, Fichou D., Menard E., Podzorov V., and Mhaisalkar S.G. (2007) Steady-state and transient photocurrents in rubrene single crystal free-space dielectric transistors. Applied Physics Letters, 91, 21, 212108. [IF: 4.0] ^##

Books

• Wu B., Mathews N., and Sum T.C. Plasmonic organic solar cells; Springer, 2017.
• Sum T.-C. and Mathews, N. Halide Perovskites: Photovoltaics, Light Emitting Devices, and Beyond; John Wiley & Sons, 2019.

Books Chapters

• Koh T.M., Ghosh B., Harikesh P.C., Mhaisallkar S., and Mathews N. (2018) "Beyond Methylammonium Lead Iodide Perovskite," in Halide Perovskites: Photovoltaics, Light Emitting Devices, and Beyond, ed, 2018, pp. 155-181.
• Boix P.P., Raga S.R., and Mathews N. (2018) "Working Principles of Perovskite Solar Cells," in Halide Perovskites: Photovoltaics, Light Emitting Devices, and Beyond, ed, 2018, pp. 81-99.
• Ager J. and Mathews N. (2018) "Perovskite Solar Cells for Photoelectrochemical Water Splitting and CO2 Reduction," in Halide Perovskites: Photovoltaics, Light Emitting Devices, and Beyond, ed, 2018, pp. 273-292.
• Wu B., Mathews N., and Sum T.C. (2017) "Concluding remarks," in SpringerBriefs in Applied Sciences and Technology, ed, 2017, pp. 101-106.
• Wu B., Mathews N., and Sum T.C. (2017) "Surface plasmon resonance," in SpringerBriefs in Applied Sciences and Technology, ed, 2017, pp. 25-31.
• Wu B., Mathews N., and Sum T.C. (2017) "Introduction," in SpringerBriefs in Applied Sciences and Technology, ed, 2017, pp. 1-23.
• Wu B., Mathews N., Sum T.C. (2017) "Plasmonic entities within the charge transporting layer," in SpringerBriefs in Applied Sciences and Technology, ed, 2017, pp. 47-80.
• Wu B., Mathews N., and Sum T.C. (2017) "Characterization plasmonic organic photovoltaic devices," in SpringerBriefs in Applied Sciences and Technology, ed, 2017, pp. 33-46.
• Wu B., Mathews N., and Sum T.-C. (2017) "Plasmonic Entities within the Charge Transporting Layer," in Plasmonic Organic Solar Cells, ed: Springer, 2017, pp. 47-80.
• Maddalena F., Boix P.P., Yu C.X., Mathews N., Soci C., and Mhaisalkar S. (2016) "Charge transport in organometal halide perovskites," in Organic-Inorganic Halide Perovskite Photovoltaics: From Fundamentals to Device Architectures, ed, 2016, pp. 201-222.

Books Chapters

• Ankit A., Chan J.Y., Nguyen L.L., Krisnadi F., and Mathews N. (2019) Large-area, flexible, integrable and transparent DEAs for haptics. Proceedings Vol. 10966, Electroactive Polymer Actuators and Devices (EAPAD) XXI, 109661W. SPIE Smart Structures + Nondestructive Evaluation, 2019, Denver, Colorado, United States.
• Thway M., Liu T., Sridharan R., Huang M., Ng X.R., Dewi H.A., Wang H., Bruno A., Mathews N., Mhaisalkar S., Duttagupta S., Stangl R., Chua S.J., Aberle A.G., and Lin F. (2019) Small-area Passivated Contact monoPolyTM Silicon Solar Cells for Tandem Device Integration. 2019 IEEE 46th Photovoltaic Specialists Conference (PVSC), Chicago, IL, USA, 2019, pp. 1064-1067, doi: 10.1109/PVSC40753.2019.8980912.
• Shukla S., Sritharan T., Xiong Q., Sum T.C., Xing G., Mathews N., Hu G., Venkatesan T., Mathew S., Su Z., and Nalla V. (2017) Investigation of Photocarrier Losses in Pyrite (FeS₂) Film Consisting Single Crystal Nanocubes. Proceedings of the 2nd World Congress on Recent Advances in Nanotechnology (RAN’17), Barcelona, Spain, 2017. Paper No. ICNNFC 118. DOI: 10.11159/icnnfc17.118.
• Ankit A., Nguyen A.C., and Mathews N. (2017) Surface texture change on-demand and microfluidic devices based on thickness mode actuation of dielectric elastomer actuators (DEAs). Proceedings Vol. 10163, Electroactive Polymer Actuators and Devices (EAPAD) 2017, 101632G. SPIE Smart Structure and Materials + Nondestructive Evaluation and Health Monitoring, 2017, Portland, Oregon, United States. DOI: 10.1117/12.2260300.
• Li M., Bhaumik, Mhaisalkar S., Mathews N., and Sum T.C. (2016) Carrier dynamics in low-dimensional perovskites. 2016 IEEE International Nanoelectronics Conference (INEC), Chengdu, China, 2016, pp.1-2. DOI: 10.1109/INEC.2016.7589434.
• Chen S., Chong W.K., Lee J., Roh K., Sari E., Mathews N., Sum T.C., and Nurmikko A. (2015) Optically Pumped Distributed Feedback Laser from Organo-Lead Iodide Perovskite Thin Films. 2015 Conference on Lasers and Electro-Optics (CLEO), San Jose, CA, USA, 2015, pp.1-2.
• Wu B., Mathews N., and Sum T.C. (2014) Ag nanoparticle-blended plasmonic organic solar cells: Performance enhancement or detraction? Proceedings Vol. 8981, Physics, Simulation and Photonic Engineering of Photovoltaic Devices III, 898111. SPIE OPTO, 2014, San Francisco, California, USA. DOI: 10.1117/12.2037744.
• Zhang L., Rao M., Kochupurackal J., Mathews N., Lam Y.M., and Mhaisalkar S.G. (2012) Effect of Nitric Acid Concentration on Doping of Thin Film Single-walled Carbon Nanotubes for Electrode Application in Transparent, Flexible Dye Sensitized Solar Cells. MRS Online Proceedings Library, 1436, 57-62 (2012). DOI: 10.1557.opl.2012.1766.