F&E1-BSS: Difference between revisions
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[[Datei:FuE6-2013-02.jpg|right|500x500px|alt=Example alt text]] |
[[Datei:FuE6-2013-02.jpg|right|500x500px|alt=Example alt text]] |
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Supervisor: [[PD Dr. Hendrik Hölscher]] |
Supervisor: [[Benutzer:Hendrik.Hoelscher | PD Dr. Hendrik Hölscher]] |
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We explore the mechanical, physical and chemical properties of nano- and micromechanical structures. Overview of our research activities is provided below. |
We explore the mechanical, physical and chemical properties of nano- and micromechanical structures. Overview of our research activities is provided below. |
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*'''Atomic Force Microscopy:''' |
*'''Atomic Force Microscopy:''' |
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The analysis and development of new techniques for the microscopy and spectroscopy of surfaces on the nano-scale allows new insights into the nanoworld. |
The analysis and development of new techniques for the microscopy and spectroscopy of surfaces on the nano-scale allows new insights into the nanoworld. |
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Current project: ''Cold atom scanning probe technology'' |
:Current project: ''Cold atom scanning probe technology'' |
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:Responsible person: [[Benutzer:Julia.Syurik | '''Dr. Julia Syurik''']] |
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*'''Nano-Tribology:''' |
*'''Nano-Tribology:''' |
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*'''Mechanical Nano- and Micro-Resonators:''' |
*'''Mechanical Nano- and Micro-Resonators:''' |
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Small mechanical resonators are frequently used as sensors. Due to their tiny size they sometimes reveal interesting physical effects not observable at the macro scale. |
Small mechanical resonators are frequently used as sensors. Due to their tiny size they sometimes reveal interesting physical effects not observable at the macro scale. |
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Current project: ''TMR sensor for AFM |
:Current project: ''TMR sensor for AFM'' |
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:Responsible person: [[Benutzer:Tobias.Meier | '''Tobias Meier''']] |
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*'''Biomimetics:''' |
*'''Biomimetics:''' |
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Some animals, insects and plants show fascinating surface effects caused by their specific microscopic surface structure. We analyse these phenomena and frequently it is possible to mimic them using nano- and microreplication techniques (cooperation with FuE3). |
Some animals, insects and plants show fascinating surface effects caused by their specific microscopic surface structure. We analyse these phenomena and frequently it is possible to mimic them using nano- and microreplication techniques (cooperation with FuE3). |
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Current projects: ''Rapid prototyping of Gecko adhesives and Production and analysis of functional biomimetic surfaces'', responsible person: '''Michael Röhrig''', ''Biomimetics of the optical surfaces of butterfly structures'', responsible person: '''Radwanul Hasan Siddique''', and ''Water harvesting technique of desert beetles'', responsible person: '''Andreas Höpf''' |
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Current projects: |
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:*''Rapid prototyping of Gecko adhesives and Production and analysis of functional biomimetic surfaces'' |
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::Responsible person: [[Benutzer:Michael.Roehrig | '''Michael Röhrig''']] |
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:*''Biomimetics of the optical surfaces of butterfly structures'' |
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::Responsible person: [[Benutzer:Radwanul.Siddique | '''Radwanul Hasan Siddique''']] |
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:*''Water harvesting technique of desert beetles'' |
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::Responsible person: [[Benutzer:Andreas.Hoepf | '''Andreas Höpf''']] |
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*'''Nano-Transistor:''' |
*'''Nano-Transistor:''' |
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Standby switches in electronic devices are currently responsible for the loss of 6.5% of the annual electricity consumption of an average household, and this value is predicted to increase to 15% by 2030. The project goal is the development of a standby switch device with nearly zero power consumption. |
Standby switches in electronic devices are currently responsible for the loss of 6.5% of the annual electricity consumption of an average household, and this value is predicted to increase to 15% by 2030. The project goal is the development of a standby switch device with nearly zero power consumption. |
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Current project: ''Development of single atom transistor |
:Current project: ''Development of single atom transistor'' |
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:Responsible person: [[Benutzer:Maryna.Kavalenka | '''Dr. Maryna Kavelenka''']] |
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Revision as of 17:43, 5 April 2013
right|500x500px|alt=Example alt text
Supervisor: PD Dr. Hendrik Hölscher
We explore the mechanical, physical and chemical properties of nano- and micromechanical structures. Overview of our research activities is provided below.
- Atomic Force Microscopy:
The analysis and development of new techniques for the microscopy and spectroscopy of surfaces on the nano-scale allows new insights into the nanoworld.
- Current project: Cold atom scanning probe technology
- Responsible person: Dr. Julia Syurik
- Nano-Tribology:
The exploration of the mechanical properties of nano-contacts and their frictional forces helps to understand the origin of friction and wear.
- Mechanical Nano- and Micro-Resonators:
Small mechanical resonators are frequently used as sensors. Due to their tiny size they sometimes reveal interesting physical effects not observable at the macro scale.
- Current project: TMR sensor for AFM
- Responsible person: Tobias Meier
- Biomimetics:
Some animals, insects and plants show fascinating surface effects caused by their specific microscopic surface structure. We analyse these phenomena and frequently it is possible to mimic them using nano- and microreplication techniques (cooperation with FuE3).
Current projects:
- Rapid prototyping of Gecko adhesives and Production and analysis of functional biomimetic surfaces
- Responsible person: Michael Röhrig
- Biomimetics of the optical surfaces of butterfly structures
- Responsible person: Radwanul Hasan Siddique
- Water harvesting technique of desert beetles
- Responsible person: Andreas Höpf
- Nano-Transistor:
Standby switches in electronic devices are currently responsible for the loss of 6.5% of the annual electricity consumption of an average household, and this value is predicted to increase to 15% by 2030. The project goal is the development of a standby switch device with nearly zero power consumption.
- Current project: Development of single atom transistor
- Responsible person: Dr. Maryna Kavelenka
