More Like this

1. Thermal management and packaging of wide and ultra-wide bandgap power devices: a review and perspective

   https://doi.org/10.1088/1361-6463/acb4ff  

   Qin, Yuan; Albano, Benjamin; Spencer, Joseph; Lundh, James Spencer; Wang, Boyan; Buttay, Cyril; Tadjer, Marko; DiMarino, Christina; Zhang, Yuhao (February 2023, Journal of Physics D: Applied Physics)

   Abstract Power semiconductor devices are fundamental drivers for advances in power electronics, the technology for electric energy conversion. Power devices based on wide-bandgap (WBG) and ultra-wide bandgap (UWBG) semiconductors allow for a smaller chip size, lower loss and higher frequency compared with their silicon (Si) counterparts, thus enabling a higher system efficiency and smaller form factor. Amongst the challenges for the development and deployment of WBG and UWBG devices is the efficient dissipation of heat, an unavoidable by-product of the higher power density. To mitigate the performance limitations and reliability issues caused by self-heating, thermal management is required at both device and package levels. Packaging in particular is a crucial milestone for the development of any power device technology; WBG and UWBG devices have both reached this milestone recently. This paper provides a timely review of the thermal management of WBG and UWBG power devices with an emphasis on packaged devices. Additionally, emerging UWBG devices hold good promise for high-temperature applications due to their low intrinsic carrier density and increased dopant ionization at elevated temperatures. The fulfillment of this promise in system applications, in conjunction with overcoming the thermal limitations of some UWBG materials, requires new thermal management and packaging technologies. To this end, we provide perspectives on the relevant challenges, potential solutions and research opportunities, highlighting the pressing needs for device–package electrothermal co-design and high-temperature packages that can withstand the high electric fields expected in UWBG devices. 

   more » « less
2. 3D Soft Architectures for Stretchable Thermoelectric Wearables with Electrical Self‐Healing and Damage Tolerance

   https://doi.org/10.1002/adma.202407073  

   Han, Youngshang; Tetik, Halil; Malakooti, Mohammad_H (August 2024, Advanced Materials)

   Abstract Flexible thermoelectric devices (TEDs) exhibit adaptability to curved surfaces, holding significant potential for small‐scale power generation and thermal management. However, they often compromise stretchability, energy conversion, or robustness, thus limiting their applications. Here, the implementation of 3D soft architectures, multifunctional composites, self‐healing liquid metal conductors, and rigid semiconductors is introduced to overcome these challenges. These TEDs are extremely stretchable, functioning at strain levels as high as 230%. Their unique design, verified through multiphysics simulations, results in a considerably high power density of 115.4 µW cm⁻²at a low‐temperature gradient of 10 °C. This is achieved through 3D printing multifunctional elastomers and examining the effects of three distinct thermal insulation infill ratios (0%, 12%, and 100%) on thermoelectric energy conversion and structural integrity. The engineered structure is lighter and effectively maintains the temperature gradient across the thermoelectric semiconductors, thereby resulting in higher output voltage and improved heating and cooling performance. Furthermore, these thermoelectric generators show remarkable damage tolerance, remaining fully functional even after multiple punctures and 2000 stretching cycles at 50% strain. When integrated with a 3D‐printed heatsink, they can power wearable sensors, charge batteries, and illuminate LEDs by scavenging body heat at room temperature, demonstrating their application as self‐sustainable electronics. 

   more » « less
3. Design of Wearable Lower Leg Orthotic Based on Six-Bar Linkage

   https://doi.org/10.1115/DETC2017-67837  

   Ghosh, Shramana; Robson, Nina; McCarthy, J. M. (August 2017, International Design Engineering Technical Conferences and Computers and Information in Engineering Conference)

   The paper presents the design of a lower leg orthotic device based on dimensional synthesis of multi-loop six-bar linkages. The wearable device is comprised of a 2R serial chain, termed the backbone, sized according to the wearer’s limb anthropometric dimensions. The paper is a result of our current efforts in proposing a systematic process for the development of 3D printed customized assistive devices for patients with reduced limb mobility, based on anthropometric data and physiological task. To design the wearable device, the physiological task of the limb is obtained using an optical motion capture system and its dimensions are set such that it matched the lower leg kinematics as closely as possible. As a next step a six-bar linkage is synthesized and ensured that its motion is as close as possible to the physiological task. Next, the 2R backbone is replaced by the wearer’s limb to provide the skeletal structure for the multiloop wearable device. During the final stage of the process the 2R backbone is relocated to parallel the human’s limb on one side, providing support and stability. The designed device can be secured to the thigh of the user to guide the lower leg without causing any discomfort and to ensure a natural physiological gait trajectory. This results in orthotic device for assisting people with lower leg injuries with compact size and better wearability. 

   more » « less
4. 3D printed electronic materials and devices.

   https://doi.org/10.1016/B978-0-08-102260-3.00013-5  

   61. Su, R.; Park, S.H.; Li, Z. (October 2018, Woodhead Publishing reviews)

   Abstract 3D printing of functional materials and devices is an emerging technology which may facilitate a higher degree of freedom in the fabrication of electronic devices in terms of material selection, 3D device form factor, morphology of target surfaces, and autonomy. This chapter discusses 3D printed electronics from the perspective of ink properties and device fabrication, including light-emitting diodes, tactile sensors and wireless powering. In combination with the progress in 3D structured light scanning, advances in computer vision, and commercial trends toward miniaturization, the prospect of autonomous, compact and portable 3D printers for electronic materials is discussed. Because the performance of 3D printed electronics is sensitively influenced by the homogeneity of printed layers, an understanding of fluid mechanics may enhance the quality of the printing and thus the performance of the resulting devices. Lastly, in order to create conformal contact between 3D printed electronics and the human body, an understanding of interfacial mechanics for 3D printed devices is suggested. 

   more » « less
5. Topology Optimization of Heat Sink for 3D Integrated Power Converters

   Xu, Xiaoqiang; Mirza, Abdul Basit; Gao, Lingfeng; Luo, Fang; Chen, Shikui (January 2022, Proceedings of the ASME International Technical Conference and Exhibition on Packaging and Integration of Electronic and Photonic Microsystems)

   This paper proposes a density-based topology optimization scheme to design a heat sink for the application of a 3D integrated SIC-based 75 kVA Intelligent Power Stage (IPS). The heat sink design considers the heat conduction and convection effects with forced air cooling. The objective function is to minimize the thermal compliance of the whole structure. A volume constraint is imposed to reduce the overall volume of the designed heat sink to make it conformal to the underlying power devices. Some numerical techniques like filtering and projection schemes are employed to render a crisp design. Some 2D benchmarks examples are first provided to demonstrate the effectiveness of the proposed method. Then a 3D heat sink, especially designed for the 3D IPS, is topologically optimized. The classic tree-like structure is reproduced to reinforce the convection effect. Some comparisons with the intuitive baseline designs are made through numerical simulation. The optimized heat sinks are shown to provide a more efficient cooling performance for the 3D integrated power converter assembly. 

   more » « less