Autonomy in materials research: a case study in carbon nanotube growth

Nikolaev, Pavel; Hooper, Daylond; Webber, Frederick; Rao, Rahul; Decker, Kevin S.; Krein, Michael; Poleski, Jason; Barto, Rick; Maruyama, Benji

doi:10.1038/npjcompumats.2016.31

Cited by 312 publications

(262 citation statements)

References 43 publications

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“…We also wish to highlight that rapid advancements are needed in the design of experiments necessary to address the challenges we have outlined. Here, machine learning and autonomous experimentation could be integrated into the current research field as they have shown great promise for carbon nanotube synthesis [131]. Ultimately, we envision processes associated with AM to be highly automated during the full-scale production workflow with robotics, especially when needed to go between instruments to print at different scales (nm to cm) and final system assembly.…”

Section: International Journal Of Antennas and Propagationmentioning

confidence: 99%

Printable Materials for the Realization of High Performance RF Components: Challenges and Opportunities

Rosker

Sandhu

Hester

et al. 2018

International Journal of Antennas and Propagation

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Printing methods such as additive manufacturing (AM) and direct writing (DW) for radio frequency (RF) components including antennas, filters, transmission lines, and interconnects have recently garnered much attention due to the ease of use, efficiency, and low-cost benefits of the AM/DW tools readily available. The quality and performance of these printed components often do not align with their simulated counterparts due to losses associated with the base materials, surface roughness, and print resolution. These drawbacks preclude the community from realizing printed low loss RF components comparable to those fabricated with traditional subtractive manufacturing techniques. This review discusses the challenges facing low loss RF components, which has mostly been material limited by the robustness of the metal and the availability of AM-compatible dielectrics. We summarize the effective printing methods, review ink formulation, and the postprint processing steps necessary for targeted RF properties. We then detail the structure-property relationships critical to obtaining enhanced conductivities necessary for printed RF passive components. Finally, we give examples of demonstrations for various types of printed RF components and provide an outlook on future areas of research that will require multidisciplinary teams from chemists to RF system designers to fully realize the potential for printed RF components.

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Section: International Journal Of Antennas and Propagationmentioning

confidence: 99%

Printable Materials for the Realization of High Performance RF Components: Challenges and Opportunities

Rosker

Sandhu

Hester

et al. 2018

International Journal of Antennas and Propagation

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“…Machine learning methods including, but not limited to, deep learning have recently been applied to more challenges in molecular and materials science fields [21]. Applications of such methods include the following: development of accelerated materials design and property prediction [22,23,24,25,26,27,28,29], process optimization [30], discovery of structure-property relationships [31,32,33], characterization of structure and property data [34], and image classification and analysis [34,35,36,37,38,39]. Such applications span multiple lengthscales (macro-to nano-scale) and a variety of material systems (inorganic oxides, electrolytes, polymers, and metals) [40].…”

Section: Machine Learning In Materials Sciencementioning

confidence: 99%

A machine learning approach to thermal conductivity modeling: A case study on irradiated uranium-molybdenum nuclear fuels

Kautz

Hagen

Johns

et al. 2019

Computational Materials Science

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“…We envisage the characterization protocol to follow this sequence: i) determination of SWCNT family distribution by Raman using 3-4 laser lines (resolution of ±50 meV); if the distribution is narrow, for example, less than ≈ 3 families observed per laser energy, then ii) perform HRTEM electron diffraction and diameter measurements (requiring resolving diameter and chiral angle differences of < 0.1 nm and 1 • respectively) and iii) carry out absorption and emission measurements (example of optical absorption spectrum for an aerogel ESI). An interesting possibility is to combine these tools with high-throughput synthesis and analysis methods [32].…”

Section: Swcnt Assignationmentioning

confidence: 99%

Molecular characterization of macroscopic aerogels of single-walled carbon nanotubes

Alemán

Vilatela

2019

Carbon

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Single-walled carbon nanotubes (SWCNT) can be assembled into various macroscopic architectures, most notably continuous fibers and films, produced currently on a kilometer-per-day scale by floating catalyst chemical vapor deposition and spinning from an aerogel of CNTs. An attractive challenge is to produce continuous fibers with controlled molecular structure with respect to the diameter, chiral angle and ultimately (n,m) indices of the constituent SWCNT "molecules". This work presents an extensive Raman spectroscopy and high-resolution transmission electron microscopy study of SWCNT aerogels produced by the direct spinning method. By retaining the open structure of the SWCNT aerogel, we reveal the presence of both semiconducting and metallic SWCNTs and determine a full distribution of families of SWCNT grouped by optical transitions. The resulting distribution matches the chiral angle distribution obtained by electron microscopy and electron diffraction. The effect of SWCNT bundling on the Raman spectra, such as the G − line shape due to plasmons activated in the far-infrared and semiconductor quenching, are also discussed. By avoiding full aggregation of the aerogel and applying the methodology introduced, rapid screening of molecular features can be achieved in large samples, making this protocol a useful analysis tool for engineered SWCNT fibers and related systems.

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Autonomy in materials research: a case study in carbon nanotube growth

Cited by 312 publications

References 43 publications

Printable Materials for the Realization of High Performance RF Components: Challenges and Opportunities

Printable Materials for the Realization of High Performance RF Components: Challenges and Opportunities

A machine learning approach to thermal conductivity modeling: A case study on irradiated uranium-molybdenum nuclear fuels

Molecular characterization of macroscopic aerogels of single-walled carbon nanotubes

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