Laser machining fundamentals: micro, nano, atomic and close-to-atomic scales

Metal additive manufacturing (AM) has been extensively studied in recent decades. Despite the significant progress achieved in manufacturing complex shapes and structures, challenges such as severe cracking when using existing alloys for laser powder bed fusion (L-PBF) AM persisted. This is due to the fact that commercial alloys are primarily designed for conventional casting or forging processes, without considering the fast cooling rates, steep temperature gradients, and multiple thermal cycles of L-PBF. To address this, there is an urgent need to develop novel alloys specifically tailored for L-PBF technologies. This review provides a comprehensive summary of the strategies employed in alloy design for L-PBF. It aims to guide future research on designing novel alloys dedicated to L-PBF instead of adapting the existing alloys for L-PBF. The review begins by discussing the features of L-PBF processes, focusing on rapid solidification and intrinsic heat treatment. Next, the printability of the four main existing alloys (Fe-, Ni-, Al-, and Ti-based alloys) is critically assessed, with a comparison to their conventional weldability. It was found that the weldability criteria are not always applicable in estimating printability. Furthermore, the review presents recent advances in alloy development and associated strategies, categorizing them into crack mitigation-oriented, microstructure manipulation-oriented, and machine learning-assisted approaches. Lastly, an outlook and suggestions are given to highlight the issues that need be addressed in future work.

“…In L-PBF, metallic parts undergo complex thermal cycles [45,46]. Initially, the powders interact with the laser beam and are melted at a fast heating rate.…”

Section: Featuresmentioning

confidence: 99%

Alloy design for laser powder bed fusion additive manufacturing: a critical review

Liu,

Zhou,

Liang

et al. 2024

“…The generated ions hit the surface of the target under the action of an electric field and sputter onto the target. In addition to the above methods of depositing thin films, nanoscale patterning is often achieved with methods including reactive ion etching (RIE), focused ion beam (FIB), femtosecond laser direct writing (FLDW), etc [140,141]. The RIE process is a plasma etching technique that adds a directional component to the etching process by using a charge.…”

Section: Modulation Of the Emission Spectrummentioning

confidence: 99%

A review on current development of thermophotovoltaic technology in heat recovery

Chen,

Guo,

Pan

et al. 2024

The burning of fossil fuels in industry results in significant carbon emissions, and the heat generated is often not fully utilized. For high-temperature industries, thermophotovoltaics (TPV) is an effective means of waste heat recovery. This review covers two aspects of high-efficiency TPV systems and industrial waste heat applications. At the system level, representative results of TPV complete systems, selective emitters and photovoltaic cells in the last decade are compiled, and key points of components to improve energy conversion efficiency is further analyzed. At the application level, the feasibility of TPV in high-temperature industrial applications is shown from the world waste heat utilization situation, and then the potential of TPV in waste heat recovery is illustrated with the steel industry as an example.

“…Meanwhile, manufacturing errors of the grooves introduce periodic exciting forces that influence the rotational stability. At present, grooves are formed through chemical etching, high precision laser texturing [309], or ultra-precision machining. Typical groove structures are 10-30 µm high.…”

Section: Instrumented Fluid Lubricated Bearingsmentioning

confidence: 99%

Design and optimization of fluid lubricated bearings operated with extreme working performances—a comprehensive review

Zhang,

Huang,

Chen

et al. 2024

Fluid lubricated bearings have been widely adopted for supporting components of high-end equipments in the field of metrology, semi-conductor, aviation, strategic defense, ultra-precision manufacturing, medical treatment and power generations. These fields all involve extreme working conditions such as ultra-high moving precision, ultra-high rotation speed, ultra-heavy bearing load, ultra-high environmental temperature, high radiation and high vacuum, which present challenges for the design and optimization of reliable fluid lubricated bearings. Breakthrough of any related bottlenecks will promote the development course of high-end equipments. To further promote the advancement of high-end equipments, this paper reviews the design and optimization of fluid lubricated bearings operated with typical extreme working performances. Targeting on the realization of extreme working perfor mances, the current challenges, the current solutions, the underlying deficiencies and the promising developing directions regarding to the design and optimization of fluid lubricat ed bearings are systematically pointed out. This paper can provide guidance for choosing suitable fluid lubricated bearings and optimizing their structures based on required extremeworking performances.