IMAGES THAT WON THE CONTEST DURING A QUARTER ARE PUT IN OUR GALLERY OF FAME. ALL OTHER IMAGES ARE PUT IN ALBUMS , ORDERED BY YEAR AND QUARTER
![I wanted to see if silicon micropillars could be protected against KOH by silicon nitride and parylene](https://1348661504.rsc.cdn77.org/.uc/ic08a65bf01014d18060052e5c7014a4f42353fa3d1ee0701c100002c0180/003-2.tif.png)
I wanted to see if silicon micropillars could be protected against KOH by silicon nitride and parylene
![A delaminated multilayer Extreme UV mirror after exposure to a free electron laser at extreme intensity.](https://1348661504.rsc.cdn77.org/.uc/i9253a9fb01014a18060025e5c70118afb247d02596c70701c100002c0180/crater-wo-scale.jpg)
A delaminated multilayer Extreme UV mirror after exposure to a free electron laser at extreme intensity.
![A silicon micro-pillar coated with silicon dioxide. On top a hydrogen catalyst of nickel-molybdenum, deposited by electro-deposition](https://1348661504.rsc.cdn77.org/.uc/i94874f3101015218060091e4c701ff42c4cb82a924ae0701c100002c0180/nimo-501.tif.png)
A silicon micro-pillar coated with silicon dioxide. On top a hydrogen catalyst of nickel-molybdenum, deposited by electro-deposition
![The cold winter days outside of the MESA+ Nanolab infiltrated the LEEM Lab creating snowflakes of a two-dimensional material](https://1348661504.rsc.cdn77.org/.uc/i1e891d09010148180600f9e5c70139ee5a82406924ee0701c100002c0180/hbn3-1.jpg)
The cold winter days outside of the MESA+ Nanolab infiltrated the LEEM Lab creating snowflakes of a two-dimensional material
![Colorful PMMA cracks after oxygen plasma](https://1348661504.rsc.cdn77.org/.uc/ibe3bfb1401015518060012e4c701decc40c034b5ce200701c100002c0180/panorama1-0012.tif.png)
Colorful PMMA cracks after oxygen plasma
![Copper oxide micro leafs](https://1348661504.rsc.cdn77.org/.uc/i5e21dbec010154180600c3e4c7015e57db8ca561bdaf0701c100002c0180/picture1-pramod-kunturu.jpg)
Copper oxide micro leafs
![Gradients of fluorescent labelled streptavidin on supported lipid bilayers in a microfluidic device.](https://1348661504.rsc.cdn77.org/.uc/i0ab76d4b01015018060076e5c701e49c99cd4be4c7070701c100002c0180/r8-c2njov10slb3b-10x50-500ms.tif.png)
Gradients of fluorescent labelled streptavidin on supported lipid bilayers in a microfluidic device.
![Plumes in Rayleigh-Benard turbulence where the fluid the heated from below and cooled from top.](https://1348661504.rsc.cdn77.org/.uc/i6a3a593601014e1806005ae5c701d93e18d46b70b3040701c100002c0180/visit0005.png)
Plumes in Rayleigh-Benard turbulence where the fluid the heated from below and cooled from top.
![Rayleigh-Benard structure.](https://1348661504.rsc.cdn77.org/.uc/i244dd06601014c18060047e5c70165caf5955ac2a1080701c100002c0180/visit0006.png)
Rayleigh-Benard structure.
![A SEM image at nanoscale of the Silicon wafer etched with deep reactive ion etching to form 3D nanostructures. The cross section is milled with the focused ion beam (FIB). The typical scalloping of the etch cycles of the Bosch process can be seen on the wa](https://1348661504.rsc.cdn77.org/.uc/if17c0b28010153180600b4e4c701f683a5262caf2f2c0701c100002c0180/cross-section-wires.jpg)
A SEM image at nanoscale of the Silicon wafer etched with deep reactive ion etching to form 3D nanostructures. The cross section is milled with the focused ion beam (FIB). The typical scalloping of the etch cycles of the Bosch process can be seen on the wa
![TEOS hard mask](https://1348661504.rsc.cdn77.org/.uc/i1bd23e0501014f18060067e5c701fdf90975068842680701c100002c0180/bsct2-12.tif.png)
TEOS hard mask
![Microscopic particle](https://1348661504.rsc.cdn77.org/.uc/i451215c301015118060086e4c70117c71d11ad91eabd0701c100002c0180/particlemicroscopic.png)
Microscopic particle
![Battery of flowers by Picasso](https://1348661504.rsc.cdn77.org/.uc/i0ecdf81201014918060016e5c7011d6f6249a4bf2db30701c100002c0180/60519-battery-of-flowers-by-picasso.jpg)
Battery of flowers by Picasso