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Books
(1). P. D. Shima, B. Raj and J. Philip, “Thermal Properties of Magnetic Nanofluids” (Chapter 4 in the Book: “Nanofluids: Synthesis, Properties and Applications”), 77-108, 2014, Nova Science Publishers, New York, USA Link
Publications in Refereed Journals
Independent Work
(1). Vijina C, Majitha K, Shima P. Damodaran*, “Platinum nanoparticle-decorated reduced graphene oxide nanosheets: A recyclable and highly efficient catalyst towards the reduction of para-nitrophenol and methylene blue”, Results in Engineering, (2023), 20, 101444 (Impact factor - 5.1)
(2) Vijina C, Majitha K, Shima P. Damodaran*, “Amine‑functionalized reduced graphene oxide‑supported silver nanoparticles for superior catalytic reduction of organic pollutants”, Environmental Science and Pollution Research, (2023), 30, 96114- 96124 (Impact factor - 5.8)
(3) Surojit Ranoo, B .B. Lahiri, Shima P. Damodaran, John Philip, “Tuning magnetic heating efficiency of colloidal dispersions of iron oxide nano-clusters by varying the surfactant concentration during solvothermal synthesis”, Journal of Molecular Liquids, (2022), 360, 119444 (Impact factor - 6.6)
(4). P. D. Shima*, “Novel nanohybrid containing magnetite nanocluster-decorated reduced graphene oxide nanosheets for heat transfer applications”, ChemistrySelect, (2021), 6, 6698-6706 (Impact factor - 2.3)
(5). P. D. Shima*, “Mesoporous magnetite nanoclusters as efficient nanocarriers for paclitaxel delivery”, ChemistrySelect, (2020), 5, 9261-9268 (Impact factor - 2.3)
(6). G. Vinodha, L. Cindrella and P. D. Shima*, “Graphene oxide based highly sensitive electrochemical snsor for detection of environmental pollutants and biomolecules”, Materials Research Express, (2019), 6, 085548 (Impact factor - 2.0)
(7). G. Vinodha, L. Cindrella and P. D. Shima*, “Graphene oxide-mesoporous iron oxide nanohybrid: An efficient reusable nanoadsorbent for the removal of organic dyes from wastewater”, Materials Research Express (2019), 6, 0850f8 (Impact factor - 2.0)
(8). G. Vinodha, B.B. Lahiri, L. Cindrella, J. Philip and P. D. Shima*, “Size-controlled synthesis of superparamagnetic magnetite nanoclusters for heat generation in an alternating magnetic field”, Journal of Molecular Liquids (2019), 281, 315-323 (Impact factor - 6.6)
(9). G. Vinodha, P. D. Shima*, and L. Cindrella, “Mesoporous magnetite nanoparticle-decorated graphene oxide nanosheets for efficient electrochemical detection of hydrazine”, Journal of Materials Science, (2019), 54, 4073-4088 ((Impact factor - 4.7)
(10). G. Vinodha, L. Cindrella and P. D. Shima*,"Novel Nanofluids Based on Magnetite Nanoclusters and Investigation on Their Cluster Size-Dependent Thermal Conductivity", The Journal of Physical Chemistry C (2018), 122, 6918-6929 (Impact factor - 4.2)
(11). G. Vinodha, L. Cindrella and P. D. Shima*, "Graphene Oxide-Wrapped Magnetite Nanoclusters: A Recyclable Functional Hybrid for Fast and Highly Efficient Removal of Organic Dyes from Wastewater", Journal of Environmental Chemical Engineering (2018), 6, 2176-2190 (Impact factor - 7.9)
(12). G. Vinodha, L. Cindrella, V. Sithara, J. Philip and P. D. Shima*, "Synthesis, characterization, thermal conductivity and rheological studies in magnetite-decorated graphene oxide nanofluids", Journal of Nanofluids (2018), 7, 11-20 (Impact factor - 1.9)
PhD and Postdoctoral Work
(13). P. D. Shima, S. Eberhard, L. Boitard, J. G. Rodriguez, Y. Wang, N. Bremond, J. Baudry, J. Bibette and F. A. Wollman, “A millifluidic study of cell-to-cell heterogeneity in growth-rate and cell-division capability in populations of isogenic cells of Chlamydomonas reinhardtii” PLOS ONE, (2015), 10(3): e0118987 (Impact factor - 3.8)
(14). P. D. Shima and J. Philip, “Role of thermal conductivity of dispersed nanoparticle on heat transfer properties of nanofluids” Industrial & Engineering Chemistry Research, (2014), 53, 980-988 (Impact factor - 4.3)
(15). J. Philip and P. D. Shima, "Thermal properties of nanofluids", Advances in Colloid and Interface Science (2012), 30, 183-184 (Impact factor - 15.2)
(16). B. Raj, P. D. Shima and J. Philip, “Thermal properties of nanofluids-recent developments” NanoTrends 10, 14-21 (2011)
(17). P. D. Shima and J. Philip, "Tuning of thermal conductivity of nanofluids using an external stimuli" The Journal of Physical Chemistry C (2011), 115, 20097 (Impact factor - 4.2)
(18). P. D. Shima, J. Philip and B. Raj, “Synthesis of aqueous and non-aqueous iron oxide nanofluids and study of temperature dependence on thermal conductivity, particle aggregation and viscosity” The Journal of Physical Chemistry C (2010), 114, 18825 (Impact factor - 4.2)
(19). P. D. Shima, J. Philip and B. Raj "Influence of aggregation on thermal conductivity in stable and unstable nanofluids" Applied Physics Letters (2010), 97, 153113 (Impact factor - 3.9)
(20). P. D. Shima, J. Philip and B. Raj “Magnetically controllable nanofluid with tunable thermal conductivity and viscosity” Applied Physics Letters (2009), 95, 133112 (Impact factor - 3.9)
(21). P. D. Shima, J. Philip and B. Raj “Role of microconvection induced by Brownian motion of nanoparticles in the enhanced thermal conductivity of stable nanofluids” Applied Physics Letters (2009), 94, 223101 (Impact factor - 3.9)
(22). J. Philip, P. D. Shima and B. Raj, “Evidence for enhanced thermal conduction through percolating structures in nanofluids” Nanotechnology (2008), 19, 305706 (Impact factor - 3.9)
(23). J. Philip, P. D. Shima and B. Raj, “Nanofluid with tunable thermal properties” Applied Physics Letters (2008), 92, 043108 (Impact factor - 3.9)
(24). J. Philip, P. D. Shima and B. Raj, “Enhancement of thermal conductivity in magnetite based nanofluid due to chainlike structures” Applied Physics Letters (2007),91, 203108 (Impact factor - 3.9)
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