| 465 - 465 |
Nanotubes keep rolling on
[Anonymous] |
| 467 - 470 |
Essential features for proactive risk management
Murashov V, Howard J |
| 471 - 471 |
Designs for living
Jones R |
| 475 - 476 |
NANOELECTRONICS From droplets to devices
Vanmaekelbergh D |
| 476 - 477 |
SCANNING TUNNELLING MICROSCOPY A DNA sequence scanned
Porath D |
| 477 - 478 |
FORCE MICROSCOPY On the charge
Schwarz UD |
| 479 - 480 |
MICROWAVE SOURCES Spin-torque oscillators get in phase
Slavin A |
| 480 - 481 |
DIAMOND NANOSTRUCTURES Isotopes for nanoelectronic devices
Itoh K |
| 481 - 481 |
CARBON NANOTUBES Sorted by DNA
Reid T |
| 483 - 491 |
Carbon nanotube tips for atomic force microscopy
Wilson NR, Macpherson JV |
| 492 - 495 |
Damping of acoustic vibrations in gold nanoparticles
Pelton M, Sader JE, Burgin J, Liu MZ, Guyot-Sionnest P, Gosztola D |
| 496 - 499 |
Optical nanocrystallography with tip-enhanced phonon Raman spectroscopy
Berweger S, Neacsu CC, Mao YB, Zhou HJ, Wong SS, Raschke MB |
| 500 - 504 |
Structural transformations in graphene studied with high spatial and temporal resolution
Warner JH, Rummeli MH, Ge L, Gemming T, Montanari B, Harrison NM, Buchner B, Briggs GAD |
| 505 - 509 |
Measurement of the quantum capacitance of graphene
Xia JL, Chen F, Li JH, Tao NJ |
| 510 - 513 |
Tunable optical forces between nanophotonic waveguides
Roels J, De Vlaminck I, Lagae L, Maes B, Van Thourhout D, Baets R |
| 514 - 517 |
Determination of protein structural flexibility by microsecond force spectroscopy
Dong MD, Husale S, Sahin O |
| 518 - 522 |
Partial sequencing of a single DNA molecule with a scanning tunnelling microscope
Tanaka H, Kawai T |
| 523 - 527 |
Evidence of intrinsic ferromagnetism in individual dilute magnetic semiconducting nanostructures
Zhang ZH, Wang XF, Xu JB, Muller S, Ronning C, Li Q |
| 528 - 532 |
Phase-locking of magnetic vortices mediated by antivortices
Ruotolo A, Cros V, Georges B, Dussaux A, Grollier J, Deranlot C, Guillemet R, Bouzehouane K, Fusil S, Fert A |
