Add to ORKGPositron annihilatation techniques are use to study the precipitation processes in quenched Al alloys of the type AlCu1.9, AlCu2.0Mg1.7 and AlSi1 at-%. From the experiments conclusions are drawn with respect to the structure and chemistry of nanometer-size precipitations which are responsible for the improved mechanical properties of these alloys
The main mechanism for the strengthening of aluminium‐copper alloys of the 2xxx type is hardening by...
Recent progress in understanding the origins of hardening in Al-1.7Cu-0.01Sn (at. %) and Al-1.1Cu-1....
A lot of light aluminium alloys achieve their favourable mechanical properties, especially their hig...
Positron annihilation lifetime and Doppler-broadened annihilation line spectroscopy were used to stu...
Adding trace elements (Cd, In, Sn) to Al‐Cu‐based alloys can significantly improve their strength by...
We present results on the structure of nano-sized particles (Guinier-Preston (GP) and Guinier-Presto...
Precipitation hardening involves solutionising, quenching and annealing steps, the latter often at v...
The precipitation kinetics of two commercial Al-Zn-Mg alloys (7005 and 7012) was studied by using di...
The precipitation kinetics of two commercial Al-Zn-Mg alloys (7005 and 7012) was studied by using di...
The precipitation kinetics of two commercial Al-Zn-Mg alloys (7005 and 7012) was studied by using di...
The precipitation kinetics of two commercial Al-Zn-Mg alloys (7005 and 7012) was studied by using di...
The precipitation kinetics of two commercial Al-Zn-Mg alloys (7005 and 7012) was studied by using di...
Aluminium-copper alloys of the 2xxx type receive their excellent mechanical properties by the format...
Aluminium-copper alloys of the 2xxx type receive their excellent mechanical properties by the format...
Positron Annihilation Spectroscopy has been used to study the microstructure in aluminum alloy AA707...
The main mechanism for the strengthening of aluminium‐copper alloys of the 2xxx type is hardening by...
Recent progress in understanding the origins of hardening in Al-1.7Cu-0.01Sn (at. %) and Al-1.1Cu-1....
A lot of light aluminium alloys achieve their favourable mechanical properties, especially their hig...
Positron annihilation lifetime and Doppler-broadened annihilation line spectroscopy were used to stu...
Adding trace elements (Cd, In, Sn) to Al‐Cu‐based alloys can significantly improve their strength by...
We present results on the structure of nano-sized particles (Guinier-Preston (GP) and Guinier-Presto...
Precipitation hardening involves solutionising, quenching and annealing steps, the latter often at v...
The precipitation kinetics of two commercial Al-Zn-Mg alloys (7005 and 7012) was studied by using di...
The precipitation kinetics of two commercial Al-Zn-Mg alloys (7005 and 7012) was studied by using di...
The precipitation kinetics of two commercial Al-Zn-Mg alloys (7005 and 7012) was studied by using di...
The precipitation kinetics of two commercial Al-Zn-Mg alloys (7005 and 7012) was studied by using di...
The precipitation kinetics of two commercial Al-Zn-Mg alloys (7005 and 7012) was studied by using di...
Aluminium-copper alloys of the 2xxx type receive their excellent mechanical properties by the format...
Aluminium-copper alloys of the 2xxx type receive their excellent mechanical properties by the format...
Positron Annihilation Spectroscopy has been used to study the microstructure in aluminum alloy AA707...
The main mechanism for the strengthening of aluminium‐copper alloys of the 2xxx type is hardening by...
Recent progress in understanding the origins of hardening in Al-1.7Cu-0.01Sn (at. %) and Al-1.1Cu-1....
A lot of light aluminium alloys achieve their favourable mechanical properties, especially their hig...