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1. Controlled Molecular Assembly of Tetrazine Derivatives on Surfaces

   https://doi.org/10.31635/ccschem.021.202101088  

   Wang, Shuo ; Liu, Shuang ; Sulkanen, Audrey ; Fox, Joseph M. ; Jia, Xinqiao ; Liu, Gang-yu ( May 2021 , CCS Chemistry)

   Zhang, Xi (Ed.)

   While self-assembly is relatively well-known and widely used to form hierarchical structures and thin film coatings, controlled assembly is less known and utilized. Our prior work has demonstrated the concept of controlled assembly of macromolecules such as star polymers (MW ~383 kDa, hydrodynamic radius R ~ 13.8 nm) in droplets. The present work extends this concept to smaller molecules, in this case, poly(ethylene glycol) bis-tetrazine (PEG-bisTz, Mn 8.1 kDa, R ~1.5 nm). The key to control molecular assembly is to first deliver ultrasmall volumes (sub-fL) of solution containing PEG-bisTz to a substrate. The solvent evaporates rapidly due to the minute volume, thus forcing the assembly of solute, whose overall size and dimension are dictated by the initial liquid geometry and size. Using pre-patterned surfaces, this work revealed that the initial liquid shape can be further tuned, and as such we could control the final assembly of solute such as PEG-bisTz molecules. The degree of control is demonstrated by varying the micropatterns and delivery conditions. This work demonstrates the validity of controlled assembly for PEG-bisTz, and as such enables 3D nanoprinting of functional materials. The technology has promising applications in nanophotonics, nanoelectronics, nanocomposite materials, and tissue engineering. 

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2. Patterning of Lyotropic Chromonic Liquid Crystals by Photoalignment with Photonic Metamasks

   https://doi.org/10.1002/adma.201606112  

   Peng, Chenhui ; Guo, Yubing ; Turiv, Taras ; Jiang, Miao ; Wei, Qi‐Huo ; Lavrentovich, Oleg D. ( March 2017 , Advanced Materials)

   Controlling supramolecular self‐assembly in water‐based solutions is an important problem of interdisciplinary character that impacts the development of many functional materials and systems. Significant progress in aqueous self‐assembly and templating has been demonstrated by using lyotropic chromonic liquid crystals (LCLCs) as these materials show spontaneous orientational order caused by unidirectional stacking of plank‐like molecules into elongated aggregates. In this work, it is demonstrated that the alignment direction of chromonic assemblies can be patterned into complex spatially‐varying structures with very high micrometer‐scale precision. The approach uses photoalignment with light beams that exhibit a spatially‐varying direction of light polarization. The state of polarization is imprinted into a layer of photosensitive dye that is protected against dissolution into the LCLC by a liquid crystalline polymer layer. The demonstrated level of control over the spatial orientation of LCLC opens opportunities for engineering materials and devices for optical and biological applications.

    

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3. Interfacial layering of hydrocarbons on pristine graphite surfaces immersed in water

   https://doi.org/10.1039/d2nr04161h  

   Arvelo, Diana M. ; Uhlig, Manuel R. ; Comer, Jeffrey ; García, Ricardo ( October 2022 , Nanoscale)

   Interfacial water participates in a wide range of phenomena involving graphite, graphite-like and 2D material interfaces. Recently, several high-spatial resolution experiments have questioned the existence of hydration layers on graphite, graphite-like and 2D material surfaces. Here, 3D AFM was applied to follow in real-time and with atomic-scale depth resolution the evolution of graphite–water interfaces. Pristine graphite surfaces upon immersion in water showed the presence of several hydration layers separated by a distance of 0.3 nm. Those layers were short-lived. After several minutes, the interlayer distance increased to 0.45 nm. At longer immersion times (∼50 min) we observed the formation of a third layer. An interlayer distance of 0.45 nm characterizes the layering of predominantly alkane-like hydrocarbons. Molecular dynamics calculations supported the experimental observations. The replacement of water molecules by hydrocarbons on graphite is spontaneous. It happens whenever the graphite–water volume is exposed to air. 

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4. Origami Biosystems: 3D Assembly Methods for Biomedical Applications

   https://doi.org/10.1002/adbi.201800230  

   Bolaños Quiñones, Vladimir A. ; Zhu, Hong ; Solovev, Alexander A. ; Mei, Yongfeng ; Gracias, David H. ( September 2018 , Advanced Biosystems)

   Conventional assembly of biosystems has relied on bottom‐up techniques, such as directed aggregation, or top‐down techniques, such as layer‐by‐layer integration, using advanced lithographic and additive manufacturing processes. However, these methods often fail to mimic the complex three dimensional (3D) microstructure of naturally occurring biomachinery, cells, and organisms regarding assembly throughput, precision, material heterogeneity, and resolution. Pop‐up, buckling, and self‐folding methods, reminiscent of paper origami, allow the high‐throughput assembly of static or reconfigurable biosystems of relevance to biosensors, biomicrofluidics, cell and tissue engineering, drug delivery, and minimally invasive surgery. The universal principle in these assembly methods is the engineering of intrinsic or extrinsic forces to cause local or global shape changes via bending, curving, or folding resulting in the final 3D structure. The forces can result from stresses that are engineered either during or applied externally after synthesis or fabrication. The methods facilitate the high‐throughput assembly of biosystems in simultaneously micro or nanopatterned and layered geometries that can be challenging if not impossible to assemble by alternate methods. The authors classify methods based on length scale and biologically relevant applications; examples of significant advances and future challenges are highlighted.

    

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5. Stearic Acid as an Atomic Layer Deposition Inhibitor: Spectroscopic Insights from AFM-IR

   https://doi.org/10.3390/nano13192713  

   Satyarthy, Saumya ; Hasan Ul Iqbal, Md ; Abida, Fairoz ; Nahar, Ridwan ; Hauser, Adam ; Cheng, Mark ; Ghosh, Ayanjeet ( October 2023 , Nanomaterials)

   Modern-day chip manufacturing requires precision in placing chip materials on complex and patterned structures. Area-selective atomic layer deposition (AS-ALD) is a self-aligned manufacturing technique with high precision and control, which offers cost effectiveness compared to the traditional patterning techniques. Self-assembled monolayers (SAMs) have been explored as an avenue for realizing AS-ALD, wherein surface-active sites are modified in a specific pattern via SAMs that are inert to metal deposition, enabling ALD nucleation on the substrate selectively. However, key limitations have limited the potential of AS-ALD as a patterning method. The choice of molecules for ALD blocking SAMs is sparse; furthermore, deficiency in the proper understanding of the SAM chemistry and its changes upon metal layer deposition further adds to the challenges. In this work, we have addressed the above challenges by using nanoscale infrared spectroscopy to investigate the potential of stearic acid (SA) as an ALD inhibiting SAM. We show that SA monolayers on Co and Cu substrates can inhibit ZnO ALD growth on par with other commonly used SAMs, which demonstrates its viability towards AS-ALD. We complement these measurements with AFM-IR, which is a surface-sensitive spatially resolved technique, to obtain spectral insights into the ALD-treated SAMs. The significant insight obtained from AFM-IR is that SA SAMs do not desorb or degrade with ALD, but rather undergo a change in substrate coordination modes, which can affect ALD growth on substrates.

    

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