His primary areas of investigation include Inorganic chemistry, Electrochemistry, Lithium, Electrolyte and Supercapacitor. His Inorganic chemistry research integrates issues from Sol-gel, Electrode potential and Coating. His Electrochemistry research incorporates elements of Cathode, Chemical engineering, Aqueous solution and Analytical chemistry.
His Lithium study combines topics from a wide range of disciplines, such as Graphite and Anode. His biological study spans a wide range of topics, including Mineralogy and Intercalation. His Supercapacitor study combines topics in areas such as Thin film, Nanotechnology and Power density.
Rudolf Holze focuses on Electrochemistry, Inorganic chemistry, Electrode, Cyclic voltammetry and Chemical engineering. His Electrochemistry study integrates concerns from other disciplines, such as Nanotechnology, Energy storage, Analytical chemistry, Polyaniline and Aqueous solution. He interconnects Platinum, Adsorption, Raman spectroscopy, Electrolyte and Lithium in the investigation of issues within Inorganic chemistry.
His Lithium study combines topics from a wide range of disciplines, such as Graphite and Anode. His Electrode research incorporates elements of Battery and Redox. His research integrates issues of Carbon and Scanning electron microscope in his study of Chemical engineering.
Rudolf Holze mainly focuses on Chemical engineering, Electrochemistry, Electrode, Supercapacitor and Nanotechnology. His Electrochemistry study incorporates themes from Electrical impedance, Electrolyte and Aqueous solution. The concepts of his Aqueous solution study are interwoven with issues in Inorganic chemistry, High voltage and Lithium.
His Electrode research is mostly focused on the topic Conductive polymer. His Supercapacitor study also includes
His primary areas of study are Electrode, Chemical engineering, Energy storage, Supercapacitor and Electrochemistry. His biological study spans a wide range of topics, including PEDOT:PSS, Lithium titanate, Scanning electron microscope, Dielectric spectroscopy and Lithium. His research in Lithium focuses on subjects like X-ray photoelectron spectroscopy, which are connected to Carbon.
He works mostly in the field of Energy storage, limiting it down to topics relating to Anode and, in certain cases, Electrolyte, Cathode and Polypyrrole, as a part of the same area of interest. His studies deal with areas such as Nanocomposite, Nanoparticle, Electrode potential, Buffer and Metal as well as Supercapacitor. His Electrochemistry research is multidisciplinary, relying on both Process engineering, Nanotechnology, High voltage and Aqueous solution.
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Carbon anode materials for lithium ion batteries
Y.P. Wu;Y.P. Wu;E. Rahm;R. Holze.
Journal of Power Sources (2003)
Electrochemical Performance of MnO2 Nanorods in Neutral Aqueous Electrolytes as a Cathode for Asymmetric Supercapacitors
Qunting Qu;Peng Zhang;Bin Wang;Yuhui Chen.
Journal of Physical Chemistry C (2009)
Cathode materials modified by surface coating for lithium ion batteries
C. Li;H.P. Zhang;L.J. Fu;H. Liu.
Electrochimica Acta (2006)
Surface modifications of electrode materials for lithium ion batteries
L.J. Fu;H. Liu;C. Li;Y.P. Wu;Y.P. Wu.
Solid State Sciences (2006)
Nickel cobaltite as an emerging material for supercapacitors: An overview
Deepak P. Dubal;Deepak P. Dubal;Pedro Gomez-Romero;Babasaheb R. Sankapal;Rudolf Holze.
Nano Energy (2015)
V2O5·0.6H2O nanoribbons as cathode material for asymmetric supercapacitor in K2SO4 solution
Q.T. Qu;Y. Shi;L.L. Li;W.L. Guo.
Electrochemistry Communications (2009)
A new cheap asymmetric aqueous supercapacitor: Activated carbon//NaMnO2
Q.T. Qu;Y. Shi;S. Tian;Y.H. Chen.
Journal of Power Sources (2009)
Electrode materials for lithium secondary batteries prepared by sol-gel methods
L.J. Fu;H. Liu;C. Li;Y.P. Wu;Y.P. Wu.
Progress in Materials Science (2005)
Effects of heteroatoms on electrochemical performance of electrode materials for lithium ion batteries
Y.P. Wu;Y.P. Wu;Elke Rahm;Rudolf Holze.
Electrochimica Acta (2002)
A cheap asymmetric supercapacitor with high energy at high power: Activated carbon//K0.27MnO2·0.6H2O
Qunting Qu;Lei Li;Shu Tian;Wenling Guo.
Journal of Power Sources (2010)
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