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1. Sustainable co-production of porous graphitic carbon and synthesis gas from biomass resources

   https://doi.org/10.1038/s44296-024-00020-0  

   Pusarapu, Vishnu; Narayana_Sarma, Rakesh; Ochonma, Prince; Gadikota, Greeshma (December 2024, npj Materials Sustainability)

   Abstract Existing pathways to produce graphite which include extraction of natural graphite impact the environment, while the conversion of fossil-driven carbon to graphite around temperatures as high as 3000 °C consumes large quantities of energy. Potassium - catalyzed graphitization is a more sustainable route and can achieve graphitic carbon formation at temperatures lower than 1000 °C, while enhancing pore formation and creating porous graphitic carbon (PGC). This two-step approach involves carbonization followed by graphitization. However, the compositions of the gaseous products have not been reported in prior studies. In this perspective, the chemical transformations underlying Alkaline Thermal Graphitization (ATG) for the co-production of synthesis gas (H₂and CO) and PGC in a single step, utilizing lignocellulosic biomass, are reported. The presence of graphitic and porous carbon structures in PGC are well suited for supercapacitor applications. This promising approach maximizes resource recovery by upgrading volatile matter to synthesis gas and low value biomass residues to porous graphitic carbon (PGC), thus co-producing sustainable fuels and energy storage materials, while lowering CO₂emissions compared to existing pathways to produce graphite. 

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2. Improved Graphitization of Lignin by Templating Using Graphene Oxide Additives

   https://doi.org/10.1021/acsabm.4c01122  

   Ike, Sandra N; Vander_Wal, Randy L (December 2024, ACS Applied Bio Materials)

   Techniques to improve the graphitization of lignin, the second most abundant natural polymer, are in great demand as a viable means to obtain cost- effective and less energy-intensive graphite for various applications. In this work, we report the effects of two-dimensional nanomaterials, graphene oxide (GO) and its derivative, reduced graphene oxide (RGO), used as templating agents for the graphitization of alkali-derived lignin. The hypothesis is that during heat temperature treatment, the GO additives act as a template that allows the lignin matrix to align on its basal planes through π−π interactions. In addition, possible chemical bonding between the GO additives and lignin may extend the two planar frameworks. Results from X-ray diffraction and Raman spectroscopy showed improved graphitic quality in the lignin-GO and lignin-RGO samples compared to pure lignin at 2500 °C. Transmission electron microscopy images and selected area electron diffraction patterns also revealed ordered nanostructures and defined polycrystalline patterns in the lignin-GO and lignin-RGO samples. This work presents a method to synthesize graphitic-like materials using carbon-based templates with the advantage that there is no need for further purification of the final material as in the case of transition metal catalysts. 

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3. Carbon Foam/CaCl ₂ ·6H ₂ O Composite as a Phase-Change Material for Thermal Energy Storage

   https://doi.org/10.1021/acs.energyfuels.3c01275  

   Jing, Yikang; Dixit, Kunal; Schiffres, Scott N; Liu, Hao (July 2023, Energy & Fuels)

   Inorganic salt hydrates are promising phase-change materials (PCMs) for thermal energy storage due to their high latent heat of fusion. However, their practical application is often limited by their unstable form, dehydration, large supercooling, and low thermal conductivity. Porous melamine foam and its carbonized derivatives are potential supporting porous materials to encapsulate inorganic salt hydrate PCMs to address these problems. This work investigates the effect of pyrolysis temperature on the morphology and structure of the carbonized foams and their thermal energy storage performance. Pyrolysis of melamine foam at 700−900 °C leads to the formation of crystalline sodium cyanate and sodium carbonate particles on the foam skeleton surface, which allows the spontaneous impregnation of the carbon foam with molten CaCl2·6H2O.The form-stable foam-CaCl2·6H2O composite effectively suppresses supercooling and dehydration, demonstrating the efficacy of carbon foam as a promising supporting material for inorganic salt hydrate PCMs. 

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4. Infrared photodetection using narrow bandgap conjugated polymers

   https://doi.org/10.1117/12.3000525  

   Azoulay, Jason D (March 2024, Proceedings SPIE)

   Rau, Ileana; Sugihara, Okihiro; Shensky, William M (Ed.)

   Low-energy, infrared (IR) photodetection forms the foundation for industrial, scientific, energy, medical, and defense applications. State-of-the-art technologies suffer from limited modularity, intrinsic fragility, high-power consumption, require cooling, and are largely incompatible with integrated circuit technologies. Conjugated polymers offer low-cost and scalable fabrication, solution processability, room temperature operation, and other attributes that are not available using current technologies. Here, we demonstrate new materials and device paradigms that enable an understanding of emergent light-matter interactions and optical to electrical transduction of IR light. Photodiodes show a response to 2.0 μm, while photoconductors respond across the near- to long-wave infrared (1–14 µm). Fundamental investigations of polymer and device physics have resulted in improving performance to levels now matching commercial inorganic detectors. This is the longest wavelength light detected for organic materials and the performance exceeds graphene at longer wavelengths. Photoconductors outperform their inorganic counterparts and operate at room temperature with higher response speeds. 

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5. TEMPLATING INDUCED GRAPHITIZATION BY GRAPHENE OXIDE DERIVED ADDITIVES: PHENOLIC RESINS, BIOMATERIALS AND ENERGY STORAGE APPLICATIONS

   Ike, Sandra N (May 2025, Penn State University)

   Interest in graphitizing hard carbons has peeked in recent years due to the applications of graphitic carbon in energy storage applications and the need to transition to greener energy and transportation. Hard carbons have initially been graphitized with the use of metal catalysts but a downside to this method is the occurrence of metal impurities in the resultant graphitic carbon which then makes it detrimental to applications. Moreover, the process of purification could also be costly. This dissertation aims to present a novel technique—templating using 2-dimensional (2D) nanomaterials—to graphitize model hard carbons. The scope of this dissertation answers the following: ❖ Does carbonization pressure affect the graphitization of soft and hard carbons? ❖ Are the characteristics/properties of 2D nanomaterials effective in templating and aiding graphitization of model hard carbons? ❖ What mechanisms are operative during templating graphitization and what are their contributions? ❖ How do the properties of the modified hard carbons influence their performance in energy storage applications? To address the aforementioned questions, in-depth studies, and novel processes were employed. The first part of this thesis explores the role of carbonization pressure in the graphitization of model soft and hard carbons. The model soft and hard carbons were subjected to carbonization under autogenic and atmospheric pressure conditions and their graphitic evolution at different high temperatures treatments was characterized. Next, the thesis explores the effect of 2D nanomaterials in the form of graphene oxide and its derivatives in inducing the graphitization of phenolic resin, novolac. Two mechanisms were identified (physical and chemical templating) as operative in aiding the graphitization of the novolac matrix. The thesis further explores the templating technique on the graphitization of a biomaterial, lignin, where methods were employed to improve the interactions between the lignin matrix and the graphene oxide additives. The results from the above-described work in the phenolic resin and biomaterial prompted the need for an in-depth understanding of the templating mechanisms and their contributing factor to graphitization. In this regard, the thesis then scrutinizes the predominant force and operative mechanism driving graphitization— physical templating versus chemical templating. Finally, the thesis assesses the influence of the properties of modified hard carbons in energy storage applications and provides strategies for performance improvement. Collectively, the important contribution of this thesis is centered on the development of 2D nanomaterial templating in inducing graphitization of hard carbons (which requires no purification process for the resultant graphitic carbon), understanding the templating mechanisms interplay in modifying and tailoring crystalline properties in hard carbons and lastly, highlighting the electrochemical performance of the modified hard carbons in energy storage applications. 

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