Driving Surface Chemistry at the Nanometer Scale Using Localized Heat and Stress

Raghuraman, Shivaranjan; Elinski, Meagan B.; Batteas, James D.; Felts, Jonathan R.

doi:10.1021/acs.nanolett.6b03457

Cited by 37 publications

(36 citation statements)

References 56 publications

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“…Tip contamination and tip wear pose other challenges, which require further improvements in tip stability and development of resists that do not leave residues after thermal conversion 126 . Finally, the effect of pressure due to the nanoscale tip on the reaction kinetics is a topic that has not been well investigated except in the case of graphene oxide 45 .…”

Section: Discussionmentioning

confidence: 99%

“…32,33,[78][79][80][81][82]84,85 . b Conversion of a functional material from a precursor 42,45,[86][87][88][89][90][91][92]94,95 . c Amorphization by short heating and fast subsequent quenching to obtain a less ordered phase 96,97 .…”

Section: Chemical Conversion Deprotection Of Functional Groupsmentioning

confidence: 99%

“…In another example, GO was thermally reduced to rGO with a heated probe to investigate the kinetics of the reaction 45 . Experimentally, the reaction kinetics was determined by correlating the probe-sample friction with the oxygen concentration of the sample (Fig.…”

Section: Conversion From a Precursor Materialsmentioning

confidence: 99%

“…Contact force/pressure: The tip-sample contact force affects the temperature and, potentially, the reaction kinetics of the t-SPL process in two ways: (i) a higher force on the cantilever increases the effective tip-sample contact area for more efficient heat transfer as discussed above and (ii) the contact force exerts a local pressure in the material under the tip, which can affect the reaction kinetics itself by reducing the reaction activation energy (Fig. 2h) 45 .…”

mentioning

confidence: 99%

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Thermal scanning probe lithography—a review

et al. 2020

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Fundamental aspects and state-of-the-art results of thermal scanning probe lithography (t-SPL) are reviewed here. t-SPL is an emerging direct-write nanolithography method with many unique properties which enable original or improved nano-patterning in application fields ranging from quantum technologies to material science. In particular, ultrafast and highly localized thermal processing of surfaces can be achieved through the sharp heated tip in t-SPL to generate high-resolution patterns. We investigate t-SPL as a means of generating three types of material interaction: removal, conversion, and addition. Each of these categories is illustrated with process parameters and application examples, as well as their respective opportunities and challenges. Our intention is to provide a knowledge base of t-SPL capabilities and current limitations and to guide nanoengineers to the best-fitting approach of t-SPL for their challenges in nanofabrication or material science. Many potential applications of nanoscale modifications with thermal probes still wait to be explored, in particular when one can utilize the inherently ultrahigh heating and cooling rates.

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Section: Discussionmentioning

confidence: 99%

Section: Chemical Conversion Deprotection Of Functional Groupsmentioning

confidence: 99%

Section: Conversion From a Precursor Materialsmentioning

confidence: 99%

mentioning

confidence: 99%

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Thermal scanning probe lithography—a review

et al. 2020

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“…In nanomanufacturing, this technique has contributed substantially to the present nanofabrication methods due to its high efficiency, high precision, and capability to fabricate diversified functional structures [2]. This technology makes it possible to fabricate nanostructures on polymers [3,4] as well as utilize nanoscale thermochemical reactions to pattern nanostructures with special electrical [5,6], wetting [7], and optical characteristics [8] on various materials. In nanometrology, the AFM thermal probe is used to measure the real temperature of the tip-substrate interface [9], the topography of the material surface [10], and the analysis of nanoscale heat transfer [11,12].…”

Section: Introductionmentioning

confidence: 99%

Nano/Microscale Thermal Field Distribution: Conducting Thermal Decomposition of Pyrolytic-Type Polymer by Heated AFM Probes

Geng

Yan

2020

Nanomaterials

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In relevant investigations and applications of the heated atomic force microscope (AFM) probes, the determination of the actual thermal distribution between the probe and the materials under processing or testing is a core issue. Herein, the polyphthalaldehyde (PPA) film material and AFM imaging of the decomposition structures (pyrolytic region of PPA) were utilized to study the temperature distribution in the nano/microscale air gap between heated tips and materials. Different sizes of pyramid decomposition structures were formed on the surface of PPA film by the heated tip, which was hovering at the initial tip–sample contact with the preset temperature from 190 to 220 °C for a heating duration ranging from 0.3 to 120 s. According to the positions of the 188 °C isothermal surface in the steady-state probe temperature fields, precise 3D boundary conditions were obtained. We also established a simplified calculation model of the 3D steady-state thermal field based on the experimental results, and calculated the temperature distribution of the air gap under any preset tip temperature, which revealed the principle of horizontal (<700 nm) and vertical (<250 nm) heat transport. Based on our calculation, we fabricated the programmable nano-microscale pyramid structures on the PPA film, which may be a potential application in scanning thermal microscopy.

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Shear‐Induced Interfacial Structural Conversion of Graphene Oxide to Graphene at Macroscale

Gao

Zhang

et al. 2020

Adv Funct Materials

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The controllable adjustment of an ideal graphene structure on the surface/ interface is important to achieve many of the potential characteristics and applications of graphene. Here, a phenomenon is observed in which friction can induce the structural conversion of graphene oxide (GO) to graphene perfectly on a macroscale sliding interface. The controlling factors and molecular interaction mechanism are further revealed by experiments and theoretical simulation. The results show that shear force drives the tribochemical reactions between the-OH group of GO and active bond of the counterpart, as well as the-OH groups of adjacent GO sheets, leading to the breakage of the COH bond. This leads to the transformation of the sp 3 C to sp 2 C, thereby forming a perfect sixmembered ring. The as-broken hydroxyl groups combine with the dangling bond of the frictional pair or capture hydrogen from the hydroxyl group of the adjacent GO sheet and generate water molecules. This study provides more information on a novel method of manipulating the interfacial structure of graphene at a macroscale by a simple sliding action. The method also provides a new way of force sensing through the detection of the released H 2 O molecules.

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Driving Surface Chemistry at the Nanometer Scale Using Localized Heat and Stress

Cited by 37 publications

References 56 publications

Thermal scanning probe lithography—a review

Thermal scanning probe lithography—a review

Nano/Microscale Thermal Field Distribution: Conducting Thermal Decomposition of Pyrolytic-Type Polymer by Heated AFM Probes

Shear‐Induced Interfacial Structural Conversion of Graphene Oxide to Graphene at Macroscale

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