2020 - Member of the European Academy of Sciences
Her scientific interests lie mostly in Inorganic chemistry, Atomic layer deposition, Oxygen, Thin film and Condensed matter physics. Her research in Inorganic chemistry intersects with topics in Perovskite and Crystal structure. Her Perovskite study results in a more complete grasp of Crystallography.
Her Oxygen research includes elements of Oxidizing agent, Redox and Polymer. Her biological study spans a wide range of topics, including Layer, Deposition, Chemical engineering and Analytical chemistry. Her Analytical chemistry study combines topics in areas such as Valence and Thermoelectric effect.
Her primary areas of study are Superconductivity, Analytical chemistry, Crystallography, Condensed matter physics and Oxygen. In Superconductivity, Maarit Karppinen works on issues like Copper, which are connected to Homologous series. Her work deals with themes such as Magnetic susceptibility, Annealing and Thin film, Atomic layer deposition, which intersect with Analytical chemistry.
Her Crystallography research integrates issues from Valence and Phase. In her work, Ferromagnetism is strongly intertwined with Magnetoresistance, which is a subfield of Condensed matter physics. Her biological study deals with issues like Inorganic chemistry, which deal with fields such as Oxide.
Her primary areas of investigation include Thin film, Atomic layer deposition, Layer, Chemical engineering and Nanotechnology. Her research integrates issues of Deposition, Luminescence, Optoelectronics, Amorphous solid and Metal in her study of Thin film. Maarit Karppinen has included themes like Carbon film, Layer by layer, Thermoelectric effect and Analytical chemistry in her Atomic layer deposition study.
Her studies in Analytical chemistry integrate themes in fields like Ferrimagnetism and Electrical resistivity and conductivity. The concepts of her Layer study are interwoven with issues in X-ray reflectivity, Inorganic chemistry and Crystal structure. Her Nanotechnology research is multidisciplinary, incorporating elements of Thermoelectric materials and Superlattice.
The scientist’s investigation covers issues in Thin film, Atomic layer deposition, Nanotechnology, Layer and Chemical engineering. Her research in Thin film intersects with topics in Deposition, Amorphous solid, Inorganic chemistry, Metal and Electrical resistivity and conductivity. Her Atomic layer deposition research also works with subjects such as
Her studies deal with areas such as Photochemistry, Lithium, Crystal structure and Superlattice as well as Layer. Her Superconductivity study introduces a deeper knowledge of Condensed matter physics. Her Condensed matter physics study integrates concerns from other disciplines, such as Perovskite and Néel temperature.
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A2B′B″O6 perovskites: A review
Sami Vasala;Maarit Karppinen.
Progress in Solid State Chemistry (2015)
Atomic layer deposition of ZnO: a review
Tommi Tynell;Maarit Karppinen.
Semiconductor Science and Technology (2014)
Inorganic Hollow Nanotube Aerogels by Atomic Layer Deposition onto Native Nanocellulose Templates
Juuso T. Korhonen;Panu Hiekkataipale;Jari Malm;Maarit Karppinen.
ACS Nano (2011)
Organic and inorganic-organic thin film structures by molecular layer deposition: A review.
Pia Sundberg;Maarit Karppinen.
Beilstein Journal of Nanotechnology (2014)
Evidence for valence fluctuation of Fe in Sr2FeMoO6−w double perovskite
J. Lindén;T. Yamamoto;Maarit Karppinen;H. Yamauchi.
Applied Physics Letters (2000)
Double-Perovskite Anode Materials Sr2MMoO6 (M = Co, Ni) for Solid Oxide Fuel Cells
Yun Hui Huang;Yun Hui Huang;Gan Liang;Mark Croft;Matti Lehtimäki.
Chemistry of Materials (2009)
Unconventional magnetic transition and transport behavior in Na 0.75 CoO 2
T. Motohashi;R. Ueda;E. Naujalis;T. Tojo.
Physical Review B (2003)
Oxygen Nonstoichiometry in YBaCo4O7+δ: Large Low-Temperature Oxygen Absorption/Desorption Capability
Maarit Karppinen;H. Yamauchi;S. Otani;T. Fujita.
Chemistry of Materials (2006)
Simultaneously enhanced thermoelectric power and reduced resistivity of NaxCo2O4 by controlling Na nonstoichiometry
T. Motohashi;E. Naujalis;R. Ueda;K. Isawa.
Applied Physics Letters (2001)
Excitation-dependent fluorescence from atomic/molecular layer deposited sodium-uracil thin films
Ville Pale;Zivile Giedraityte;Xi Chen;Olga Lopez-Acevedo.
Scientific Reports (2017)
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