000199224 001__ 199224
000199224 005__ 20190812205758.0
000199224 02470 $$2ISI$$a000333521100031
000199224 020__ $$a978-1-4799-0041-1
000199224 020__ $$a978-1-4799-0039-8
000199224 037__ $$aCONF
000199224 245__ $$aOn-chip Mass Sensing at the Physical Limits of Nanoelectromechanical Systems
000199224 269__ $$a2013
000199224 260__ $$bIeee$$c2013$$aNew York
000199224 300__ $$a5
000199224 336__ $$aConference Papers
000199224 520__ $$aA tunable and self-regulating on-chip carbon nanotube based mass balance is presented for small-size and low-cost environmental and healthcare applications. Tube stretching and a phase-locked loop topology make the system widely universal and invariant to nanotube characteristics. Operational for tube eigenfrequencies up to 385MHz, the circuit integration in a 180nm technology achieves instantaneous zeptogram resolution, while yoctogram precision is obtained within the tenth of a second. These figures of merit range at the physical limits of carbon nanotube resonators.
000199224 700__ $$0244588$$g166554$$aKauth, Christian
000199224 700__ $$0244585$$g111342$$aPastre, Marc
000199224 700__ $$aKayal, Maher$$g105540$$0240539
000199224 7112_ $$a5th IEEE International Workshop on Advances in Sensors and Interfaces (IWASI)
000199224 773__ $$t2013 5Th Ieee International Workshop On Advances In Sensors And Interfaces (Iwasi)$$q131-135
000199224 909C0 $$xU11978$$pELAB$$0252315
000199224 909CO $$pconf$$pSTI$$ooai:infoscience.tind.io:199224
000199224 917Z8 $$x105540
000199224 937__ $$aEPFL-CONF-199224
000199224 973__ $$rREVIEWED$$sPUBLISHED$$aEPFL
000199224 980__ $$aCONF