Development of low noise cantilever deflection sensor for multienvironment frequency-modulation atomic force microscopy

Abstract: We have developed a low noise cantilever deflection sensor with a deflection noise density of 17fm∕Hz by optimizing the parameters used in optical beam deflection (OBD) method. Using this sensor, we have developed a multienvironment frequency-modulation atomic force microscope (FM-AFM) that can achieve true molecular resolution in various environments such as in moderate vacuum, air, and liquid. The low noise characteristic of the deflection sensor makes it possible to obtain a maximum frequency sensitivity li… Show more

“…The AFM experiments were performed by a custom-built AFM head with an ultralow noise cantilever deflection sensor [3,29] and a photothermal excitation setup [30]. The AFM head was controlled with a commercially available AFM controller (ARC2: Asylum Research).…”

“…Cantilever excitation methods To achieve the theoretically-limited performance given by equation (10), we should overcome two technical difficulties: the detection and excitation of the cantilever oscillation. So far, a number of detection techniques for a small cantilever have been reported [19,20,3,21,22,23]. In contrast, the excitation method for a small cantilever has yet to be established.…”

“…The solid lines show the experimentally measured spectra while the dotted lines show the frequency spectral density (n fB ) corresponding to the noise arising from the thermal Brownian motion of the cantilever. The values of n fB were calculated by following equation [3,38].…”

“…Several groups have presented practical ways to fabricate small cantilevers with a high resonance frequency [16,17,18]. In addition, several sophisticated designs for low noise and wideband deflection sensors for small cantilevers have been proposed [19,20,3,21,22,23].…”

“…However, recent advancements in its instrumentation [3] have made it possible to operate FM-AFM with true atomic resolution even in liquid [4], which has opened up new applications in chemistry [5,6] and biology [7,8,9,10,11,12,13,14,15]. To obtain true atomicresolution images by FM-AFM, it is required to detect short-range interaction force acting between the tip front atom and surface atom.…”

Atomic-resolution imaging in liquid by frequency modulation atomic force microscopy using small cantilevers with megahertz-order resonance frequencies

“…The AFM experiments were performed by a custom-built AFM head with an ultralow noise cantilever deflection sensor [3,29] and a photothermal excitation setup [30]. The AFM head was controlled with a commercially available AFM controller (ARC2: Asylum Research).…”

“…Cantilever excitation methods To achieve the theoretically-limited performance given by equation (10), we should overcome two technical difficulties: the detection and excitation of the cantilever oscillation. So far, a number of detection techniques for a small cantilever have been reported [19,20,3,21,22,23]. In contrast, the excitation method for a small cantilever has yet to be established.…”

“…The solid lines show the experimentally measured spectra while the dotted lines show the frequency spectral density (n fB ) corresponding to the noise arising from the thermal Brownian motion of the cantilever. The values of n fB were calculated by following equation [3,38].…”

“…Several groups have presented practical ways to fabricate small cantilevers with a high resonance frequency [16,17,18]. In addition, several sophisticated designs for low noise and wideband deflection sensors for small cantilevers have been proposed [19,20,3,21,22,23].…”

“…However, recent advancements in its instrumentation [3] have made it possible to operate FM-AFM with true atomic resolution even in liquid [4], which has opened up new applications in chemistry [5,6] and biology [7,8,9,10,11,12,13,14,15]. To obtain true atomicresolution images by FM-AFM, it is required to detect short-range interaction force acting between the tip front atom and surface atom.…”

Atomic-resolution imaging in liquid by frequency modulation atomic force microscopy using small cantilevers with megahertz-order resonance frequencies

Overview of Atomic Force Microscopy

References