Revealing Subsurface Vibrational Modes by Atom-Resolved Damping Force Spectroscopy

Abstract: We propose to use the damping signal of an oscillating cantilever in dynamic atomic force microscopy as a noninvasive tool to study the vibrational structure of the substrate. We present atomically resolved maps of damping in carbon nanotube peapods, capable of identifying the location and packing of enclosed Dy@C82 molecules as well as local excitations of vibrational modes inside nanotubes of different diameter. We elucidate the physical origin of damping in a microscopic model and provide quantitative inter… Show more

“…8.7 [28]. In that case the AFM tip was reported to have an "atomically sharp" apex, whose radius R was estimated to be less than 0.5 nm [5]. The sharpness and the effective shape of the tip apex were deduced by deconvoluting AFM images of empty SWNTs, used for calibration.…”

“…These hybrid structures have been investigated predominantly using electrons as a probe in electronic transport measurements [10,21], transmission electron microscopy (TEM) [22,23], and scanning tunnelling microscopy/spectroscopy (STM/STS) [24,25] studies. Figure 8.5 shows TEM images of the (Dy@C 82 )@SWNT sample used in [5], in which the fullerene cages are imaged as circles and the enclosed Dy atoms as dark spots positioned off the center, clearly representing the "quasi" one-dimensional crystal formation [26] of encapsulated Dy@C 82 endohedral metallofullerene molecules. In the process of sample preparation, the Dy@C 82 molecules were encapsulated into open-ended SWNTs with different diameters by heating their mixture in a platinum crucible under 10 −6 Torr at 440 • C for 5 days [27].…”

“…The technique based on the nonlinear detection of ultrasonic oscillation in elastically "indented" samples, however, yields subsurface images with nanometer-scale resolution at best. Building on the high spatial resolution and sensitivity of dynamic non-contact AFM, Damping Force Spectroscopy (DFS) [5] has been introduced as a non-invasive tool to study subsurface structure and vibrational modes in complex molecular systems at the atomic scale. Carbon nanotube peapods [6][7][8] consisting of linear chains of fullerenes enclosed in single-walled carbon nanotubes (SWNTs) [9] have been chosen as a prominent example of supramolecular compounds.…”

Revealing Subsurface Vibrational Modes by Atomic-Resolution Damping Force Spectroscopy

“…8.7 [28]. In that case the AFM tip was reported to have an "atomically sharp" apex, whose radius R was estimated to be less than 0.5 nm [5]. The sharpness and the effective shape of the tip apex were deduced by deconvoluting AFM images of empty SWNTs, used for calibration.…”

“…These hybrid structures have been investigated predominantly using electrons as a probe in electronic transport measurements [10,21], transmission electron microscopy (TEM) [22,23], and scanning tunnelling microscopy/spectroscopy (STM/STS) [24,25] studies. Figure 8.5 shows TEM images of the (Dy@C 82 )@SWNT sample used in [5], in which the fullerene cages are imaged as circles and the enclosed Dy atoms as dark spots positioned off the center, clearly representing the "quasi" one-dimensional crystal formation [26] of encapsulated Dy@C 82 endohedral metallofullerene molecules. In the process of sample preparation, the Dy@C 82 molecules were encapsulated into open-ended SWNTs with different diameters by heating their mixture in a platinum crucible under 10 −6 Torr at 440 • C for 5 days [27].…”

“…The technique based on the nonlinear detection of ultrasonic oscillation in elastically "indented" samples, however, yields subsurface images with nanometer-scale resolution at best. Building on the high spatial resolution and sensitivity of dynamic non-contact AFM, Damping Force Spectroscopy (DFS) [5] has been introduced as a non-invasive tool to study subsurface structure and vibrational modes in complex molecular systems at the atomic scale. Carbon nanotube peapods [6][7][8] consisting of linear chains of fullerenes enclosed in single-walled carbon nanotubes (SWNTs) [9] have been chosen as a prominent example of supramolecular compounds.…”

Revealing Subsurface Vibrational Modes by Atomic-Resolution Damping Force Spectroscopy

“…In the non-contact AFM operation, a cantilever with the sharp tip is oscillated at resonant frequency above the surface and its frequency provides an atomic resolution image of the surface. In addition to the frequency, information of damped amplitude of the oscillation also offers a structural atomic image and an insight into atomic dynamics such as phonon local density of states on the surface [2][3][4][5][6][7][8][9]. The origin of energy dissipation of the damped oscillation, however, has been the subject of debate over the past decade.…”

Energy Dissipation of AFM Studied by MD/Continuum Coupling Model

“…Dissipation has been observed in noncontact atomic force microscopy (AFM), and a map of the dissipation shows atomic-scale features for several surfaces [1][2][3][4][5][6][7][8][9]. The origin of dissipation in AFM has been intensively discussed by theoretical and computational methods [10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26].…”

Analysis of Tip Stability in Adhesion Process in AFM Using Potential Energy Surface: Stability Versus Dissipation