﻿Figure 1:
Temperature (K)
resisitivity (microOhmm)

The resistivity of titanium alloys Ti-64 (Ti-6Al-4V) and Ti-6242 (Ti-6Al-2Sn-4Zr-2Mo-0.2Si) 
Ti-6242(AS) and Ti-64(AS) materials in the as-supplied state achieve zero resistivity. 
The Ti-64(BR) and Ti(64(IT) were heat treated using the schedules for bronze-route Nb3Sn and internal tin Nb3Sn strands respectively



Figure 2:
Temperature (K) 
Resistivity (microOhmm)
The resistivity of titanium alloys Ti-64 (AS) (Ti-6Al-4V as supplied) as a function of field: 0.5 T steps between 0T and 7.5T


Figure 3:
Temperature (K) 
Resistivity (microOhmm)
The resistivity of titanium alloys Ti-6242 (AS) as a function of field: 0.125 T steps between 0T and 0.875T
Repeat measurement at 0T

Figure 4
Temperature (K) 
Resistivity (microOhmm)
The resistivity of titanium alloys Ti-64 (BR) (Ti-6Al-4V bronze route heat treated) 
function of field: 0.5 T steps between 0T and 8T

Figure 5
Temperature (K) 
Magnetic field (T)
Data for Ti-64(AS), Ti-64(BR), Ti-64(IT), Ti-6242(AS)
The fit for each of the lines is then presented, Temperature, Field(Ti-64(AS), Ti-64(BR), Ti-64(IT), Ti-6242(AS))

Figure 6
4 AXES PLOT
EJ- and IV
The data is presented: Current(A), current density(Amm^-2), Voltage(V), Electric field(microVm-1)
This is for Ti-64(AS) 
Traces are for Applied field of 0T to 2.5T in incremenets of 0.5T

Figure 7
4 AXES PLOT
EJ- and IV
The data is presented: Current(A), current density(Amm^-2), Voltage(V), Electric field(microVm-1)
This is for Ti-64(BR) 
Traces are for Applied field of 0T to 4.5T in incremenets of 0.5T


Figure 7
4 AXES PLOT
EJ- and IV
The data is presented: Current(A), current density(Amm^-2), Voltage(V), Electric field(microVm-1)
This is for  Ti-6242(AS), Ti-64(IT),Ti-64(BR),Ti-64(AS)




