What are the current research efforts aimed at improving the performance and efficiency of hBN-based solid lubricants?
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Current research efforts aimed at improving the performance and efficiency of hBN-based solid lubricants include exploring the synergy between hBN and other materials such as silver (Ag) . The combination of hBN and Ag has been found to offer low friction and wear over a broad temperature range, from room temperature to 800 °C . Another approach is the use of core-shell structured h-BN@Ni powders, which improve the wettability of h-BN with alloy substrates, resulting in enhanced strength, plasticity, and wear resistance . Additionally, the addition of h-BN micro-powders to vermicular graphite cast iron (VGI) has been shown to improve the processability of the material and reduce tool wear during turning tests . In-situ TiB2-TiN-SiC composite coatings, with simultaneous addition of hBN and SiC, have also been investigated to achieve the benefits of hBN as a solid lubricant without compromising mechanical properties . These research efforts aim to optimize the performance and efficiency of hBN-based solid lubricants for various applications.
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| The provided paper does not discuss current research efforts aimed at improving the performance and efficiency of hBN-based solid lubricants. The paper focuses on the usage of hBN as a process aid in the polymer industry and its effect on the processability of linear low density polyethylene. | |
1 Citations | The provided paper does not specifically mention current research efforts aimed at improving the performance and efficiency of hBN-based solid lubricants. |
2 Citations | The provided paper does not discuss current research efforts aimed at improving the performance and efficiency of hBN-based solid lubricants. |
1 Citations | The provided paper does not mention any current research efforts aimed at improving the performance and efficiency of hBN-based solid lubricants. |
4 Citations | The current research efforts mentioned in the paper focus on improving the wettability of h-BN with alloy substrates by using core-shell structured h-BN@Ni powders. |
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