1. E = 4.0 GeV (nominal) PMU g = 5 mm NbTi Nb3Sn g = 4 mm g = 4 mm 145 m
magnetic gap is 2.3 mm larger than vac. gap, g
PMU
g = 5 mm
NbTi
Nb3Sn
g = 4 mm
g = 4 mm
4.8 keV SASE
7.6 keV SASE
145 m
6.8 keV
SASE
gex,y = 0.40 mm
Ipk = 1 kA
sE = 500 keV
b = 16 m
20% Lu margin
3.4-m seg’s
1.0-m breaks
1 und. missing
1.5 keV low-lim.
lu = 25.6 mm, 18.4 mm, 16.8 mm

2. E = 4.2 GeV (stretch) PMU NbTi g = 5 mm Nb3Sn g = 4 mm g = 4 mm 145 m
magnetic gap is 2.3 mm larger than vac. gap, g
PMU
NbTi
g = 5 mm
Nb3Sn
g = 4 mm
g = 4 mm
145 m
8.2 keV SASE
gex,y = 0.40 mm
Ipk = 1 kA
sE = 500 keV
b = 16 m
20% Lu margin
3.4-m seg’s
1.0-m breaks
1 und. missing
1.5 keV low-lim.
~7 keV HXRSS limit
lu = 25.6 mm, 18.4 mm, 16.8 mm

3. E = 4.8 GeV (20% upgrade) PMU g = 5 mm NbTi g = 4 mm 145 m Nb3Sn
magnetic gap is 2.3 mm larger than vac. gap, g
PMU
g = 5 mm
NbTi
g = 4 mm
10 keV
SASE
145 m
Nb3Sn
g = 4 mm
8.3 keV HXRSS limit
lu = 25.6 mm, 18.4 mm, 16.8 mm

5. E = 4.0 GeV (nominal) – all 5-mm vac. gaps
PMU
g = 5 mm
NbTi
Nb3Sn
g = 5 mm
g = 5 mm
145 m
lu = 25.6 mm, 19.2 mm, 17.6 mm

6. E = 4.2 GeV - all 5-mm vac. gaps PMU NbTi Nb3Sn g = 5 mm g = 5 mm
lu = 25.6 mm, 19.2 mm, 17.6 mm

7. E = 4.8 GeV - all 5-mm vac. gaps PMU NbTi g = 5 mm g = 5 mm 145 m
Nb3Sn
g = 5 mm
7.9 keV HXRSS limit
lu = 25.6 mm, 19.2 mm, 17.6 mm

8. E = 3.4 GeV (drop 5 Cryo-Modules)
NbTi
g = 4 mm
145 m
Nb3Sn
g = 4 mm
lu = 25.6 mm, 18.4 mm, 16.8 mm