| 71 - 71 |
Getting to know the public
[Anonymous] |
| 72 - 72 |
Applicability of AFM in cancer detection
Lekka M, Laidler P |
| 72 - 73 |
Applicability of AFM in cancer detection Reply
Cross SE, Jin YS, Rao JY, Gimzewski JK |
| 75 - 75 |
Nanotechnology, energy and markets
Jones R |
| 79 - 80 |
New insights into public perceptions
Currall SC |
| 81 - 82 |
Atomic waterwheels go to work
Brandbyge M |
| 82 - 83 |
Shorting neurons with nanotubes
Silva GA |
| 84 - 85 |
Nanoparticles reconstruct lipids
Dawson KA, Salvati A, Lynch I |
| 85 - 86 |
Nanotubes light up cells
Krauss TD |
| 87 - 90 |
Cultural cognition of the risks and benefits of nanotechnology
Kahan DM, Braman D, Slovic P, Gastil J, Cohen G |
| 91 - 94 |
Religious beliefs and public attitudes toward nanotechnology in Europe and the United States
Scheufele DA, Corley EA, Shih TJ, Dalrymple KE, Ho SS |
| 95 - 98 |
Deliberating the risks of nanotechnologies for energy and health applications in the United States and United Kingdom
Pidgeon N, Harthorn BH, Bryant K, Rogers-Hayden T |
| 99 - 102 |
Current-driven atomic waterwheels
Dundas D, McEniry EJ, Todorov TN |
| 103 - 107 |
Donor deactivation in silicon nanostructures
Bjork MT, Schmid H, Knoch J, Riel H, Riess W |
| 108 - 113 |
Imaging the electrical conductance of individual carbon nanotubes with photothermal current microscopy
Tsen AW, Donev LAK, Kurt H, Herman LH, Park J |
| 114 - 120 |
Multimodal optical sensing and analyte specificity using single-walled carbon nanotubes
Heller DA, Jin H, Martinez BM, Patel D, Miller BM, Yeung TK, Jena PV, Hobartner C, Ha T, Silverman SK, Strano MS |
| 121 - 125 |
One-step DNA-programmed growth of luminescent and biofunctionalized nanocrystals
Ma N, Sargent EH, Kelley SO |
| 126 - 133 |
Carbon nanotubes might improve neuronal performance by favouring electrical shortcuts
Cellot G, Cilia E, Cipollone S, Rancic V, Sucapane A, Giordani S, Gambazzi L, Markram H, Grandolfo M, Scaini D, Gelain F, Casalis L, Prato M, Giugliano M, Ballerini L |
