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Bibliographic Details
Main Authors: Peters, Adam B., Zhang, Dajie, Chen, Samuel, Ott, Catherine, Oses, Corey, Curtarolo, Stefano, McCue, Ian, Pollock, Tresa, Prameela, Suhas Eswarappa
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2309.04053
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author Peters, Adam B.
Zhang, Dajie
Chen, Samuel
Ott, Catherine
Oses, Corey
Curtarolo, Stefano
McCue, Ian
Pollock, Tresa
Prameela, Suhas Eswarappa
author_facet Peters, Adam B.
Zhang, Dajie
Chen, Samuel
Ott, Catherine
Oses, Corey
Curtarolo, Stefano
McCue, Ian
Pollock, Tresa
Prameela, Suhas Eswarappa
contents Hypersonic vehicles must withstand extreme conditions during flights that exceed five times the speed of sound. These systems have the potential to facilitate rapid access to space, bolster defense capabilities, and create a new paradigm for transcontinental earth-to-earth travel. However, extreme aerothermal environments create significant challenges for vehicle materials and structures. This work addresses the critical need to develop resilient refractory alloys, composites, and ceramics. We will highlight key design principles for critical vehicle areas such as primary structures, thermal protection, and propulsion systems; the role of theory and computation; and strategies for advancing laboratory-scale materials to flight-ready components.
format Preprint
id arxiv_https___arxiv_org_abs_2309_04053
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Materials Design for Hypersonics
Peters, Adam B.
Zhang, Dajie
Chen, Samuel
Ott, Catherine
Oses, Corey
Curtarolo, Stefano
McCue, Ian
Pollock, Tresa
Prameela, Suhas Eswarappa
Materials Science
Hypersonic vehicles must withstand extreme conditions during flights that exceed five times the speed of sound. These systems have the potential to facilitate rapid access to space, bolster defense capabilities, and create a new paradigm for transcontinental earth-to-earth travel. However, extreme aerothermal environments create significant challenges for vehicle materials and structures. This work addresses the critical need to develop resilient refractory alloys, composites, and ceramics. We will highlight key design principles for critical vehicle areas such as primary structures, thermal protection, and propulsion systems; the role of theory and computation; and strategies for advancing laboratory-scale materials to flight-ready components.
title Materials Design for Hypersonics
topic Materials Science
url https://arxiv.org/abs/2309.04053