M. Hans scite author profile

Magnesium-based lightweight structural materials exhibit potential for energy savings. However, the state-of-the-art quest for novel compositions with improved properties through conventional bulk metallurgy is time, energy, and material intensive. Here, the opportunities provided by combinatorial thin film materials design for the sustainable development of magnesium alloys are evaluated. To characterise the impurity level of (Mg,Ca) solid solution thin films within grains and grain boundaries, scanning transmission electron microscopy and atom probe tomography are correlatively employed. It is demonstrated that control of the microstructure enables impurity levels similar to bulk-processed alloys. In order to substantially reduce time, energy, and material requirements for the sustainable development of magnesium alloys, we propose a three-stage materials design strategy: (1) Efficient and systematic investigation of composition-dependent phase formation by combinatorial film growth. (2) Correlation of microstructural features and mechanical properties for selected composition ranges by rapid alloy prototyping. (3) Establishment of synthesis–microstructure–property relationships by conventional bulk metallurgy.

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Thermal Stability and Mechanical Properties of Sputtered (Hf,Ta,V,W,Zr)-Diborides

Kirnbauer

Wagner

Moraes

et al. 2020

SSRN Journal

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Time-Optimal Turn to a Heading: An Improved Analytic Solution

Grimm

Hans

1998

Journal of Guidance, Control, and Dynamics

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Aircraft turning performance in the horizontal plane is addressed. The task is to reach a speci ed heading and speed in minimum time. The objective is to obtain a closed-form feedback expression for the optimal turn rate in the case in which load-factor constraints do not become active. The starting point is the boundary-value problem derived from the necessary conditionsof optimal control. An analyticsolution results for constant maximum thrust and a parabolicdrag polar with constant coef cients. The extension to previous results is twofold: First, the solution is determined for all boundary conditions in the ight envelope. In many cases a composite structure made up of two different control types occurs. Second, the dynamic model includes the drag induced by the vertical lift component, which was neglected in previous work. The feedback expression for the optimal turn rate is utilized to guide an aircraft with realistic dynamics. The desired terminal conditions are reached accurately as long as load-factor constraints do not become active. The agreement of simulated ight paths using this guidance law and optimal turns obtained from open-loop trajectory optimization depends on the particular boundary conditions. Nomenclature c D0 = zero-lift drag coef cient c L = lift coef cient D = drag g = gravitational acceleration k = factor in the drag polar M = Mach number m = aircraft mass q = dynamic pressure S = reference wing area T = thrust u = turn rate P Â u s = steady-state turn rate V = speed W = weight, m £ g ¹ = bank angle ½ = air density Â = heading angle

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Energy demand assessment of electrified drivetrains in material extraction and system manufacturing

Ernst

Hans

Eckstein

2012

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M. Hans

Thermal stability and mechanical properties of sputtered (Hf,Ta,V,W,Zr)-diborides

Opportunities of combinatorial thin film materials design for the sustainable development of magnesium-based alloys

Thermal Stability and Mechanical Properties of Sputtered (Hf,Ta,V,W,Zr)-Diborides

Time-Optimal Turn to a Heading: An Improved Analytic Solution

Energy demand assessment of electrified drivetrains in material extraction and system manufacturing

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