London Centre for Nanotechnology

London Centre for Nanotechnology
Established 2003
Director Professor Gabriel Aeppli
Professor Milo Shaffer
Administrative staff
Around 130
Location London, United Kingdom
Website London Centre for Nanotechnology

The London Centre for Nanotechnology is a multidisciplinary research centre in physical and biomedical nanotechnology in London, United Kingdom. It brings together two institutions that are world leaders in nanotechnology, University College London and Imperial College London. It was conceived from the outset with a management structure allowing for a clear focus on exploitation and commercialisation. Although based at UCL's campus in Bloomsbury, the LCN includes research in departments of Imperial's South Kensington campus.

The LCN's work requires it to draw on the combined skills of multiple departments, including medicine, chemistry, physics, electrical and electronic engineering, biochemical engineering, materials and earth sciences, and two leading business centres. The LCN’s stated vision is to become Europe’s premier research centre in nanotechnology applied to health care, information technology and the environment.

History

The London Centre for Nanotechnology was established as a joint venture between UCL and Imperial College London in 2003 following the award of a £13.65m higher education grant under the Science Research Infrastructure Fund.[1][2] In October 2006 the LCN installed the first monochromated electron microscope in the UK at its site on the Imperial College London campus.[3]

In October 2008 the LCN published research about the possibility of using microscopic "nanoprobes" to discover new drugs to combat antibiotic resistance.[4] In October 2009 a team at the Science and Technology Facilities Council's ISIS facility led by Stephen Bramwell of the LCN published research showing that single magnetic charges be made to behave and interact like electrical ones through the use of the magnetic monopoles that exist in spin ice.[5]

Research areas

Scientists in the photolithography laboratory in the London Centre for Nanotechnology cleanroom. The room is lit with orange lighting to avoid damage to the photoresist which could occur if there were ambient light at short wavelengths.
Chemical vapour deposition machine in the diamond laboratory of the London Centre for Nanotechnology

LCN's research is organised around three themes, which it characterizes as follows:

Information Technology: Computing and communications needs continue to grow and underpin all other human endeavours. Current technologies are limited and new nanotechnology-driven paradigms such as quantum computing and spintronics are needed.

Health care: Under development are specialised sensors and novel cancer-diagnosis systems, as well as new insights into cellular biophysics and nanotechnology-based instrumentation.

Planet Care: The LCN uses its expertise, ranging from biology to chemistry and materials science, to conduct research in areas including novel photovoltaics, new approaches to exploring current energy supplies, low-power lighting and computing, new materials, instrumentation for the nuclear industry, and storing hydrogen efficiently at room temperature.

IT Healthcare Planet Care
Quantum computing Medical diagnostics & sensor Photovoltaics/solar cells
Material growth/synthesis Nanoscale drug testing Fuel cells and electrodes
Scan-probes Bio-inspired materials Hydrogen storage
Modelling/simulation Lab on chip/tip Composite Materials
Novel materials Molecular simulation Novel displays
Hybrid devices and systems Disease studies Nuclear fusion and fission
Large-scale electronics Cell & tissue-device interfaces Eco-processing
MEMS and vacuum devices Medical imaging Novel manufacturing methods
Spintronics/superconductors Cell biomechanics Nanoparticle applications
Photonics Multifunctional bionanoparticles Fossil fuel exploration

Facilities

LCN has access to a range of facilities include:
• Nano-CAD: techniques to simulate, visualize and design nano-scale structures and devices in the biological and non-biological areas; first principles atomic/molecular level theory, systems modelling and other powerful computational tools.
• Nano-characterisation: the full range of optical, electron, ion and scan-probe based technologies required to image and understand nanostructures in both the biological and non-biological areas - measuring nano-electrical, structural, mechanical, rheological, acoustic, thermal and magnetic properties.
• Nano-fabrication: large clean-room space with the ability to produce nano-materials and devices using various biological and non-biological materials; silicon, III-V fabrication and unconventional fabrication – for example, of organics and diamond.
• Systems: the range of techniques required to translate nanotechnology into workable products for industry; hybridisation and integration techniques, error handling and re-routing algorithms, methods to connect bio- and non-bio systems.

References

  1. "London's little idea". BBC News. 27 January 2003. Retrieved 31 October 2010.
  2. "Nanotech under the microscope". BBC News. 12 June 2003. Retrieved 31 October 2010.
  3. "UK researchers unveil country's most powerful microscope". Chemistry World. 20 October 2006. Retrieved 31 October 2010.
  4. "'Nanotech search' for antibiotics". BBC News. 12 October 2008. Retrieved 31 October 2010.
  5. "'Magnetic electricity' discovered". BBC News. 14 October 2009. Retrieved 31 October 2010.

External links

Coordinates: 51°31′31″N 0°07′59″W / 51.525387°N 0.133027°W / 51.525387; -0.133027

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