THE TAC IR FEL OSCILLATOR FACILITY PROJECT* 
B. Ketenoglu#, A. Aksoy, O. Yavas, M. Tural, O. Karsli, Ankara University, Ankara, Turkey  
S. Ozkorucuklu, S. Demirel University, Isparta, Turkey 
P. Arikan, E. Kasap, Gazi University, Ankara, Turkey  
H. Yildiz, Dumlupınar University, Kütahya, Turkey 
B. Bilen, Doğuş University, İstanbul, Turkey 
H. Aksakal, Niğde University, Niğde, Turkey 
I. Tapan, Uludağ University, Bursa, Turkey 
Abstract 
The TAC (Turkish Accelerator Center) IR FEL 
Oscillator facility, which has been supported by Turkish 
State Planning Organization (SPO) since 2006, will be 
based on a 15-40 MeV electron linac accompanying two 
different undulators with 2.5 cm and 9 cm periods in 
order to obtain IR FEL ranging between 2-250 microns. 
The electron linac will consist of two sequenced modules, 
each housing two 9-cell superconducting TESLA cavities 
for cw operation. It is planned that the TAC IR FEL 
facility will be completed in 2012 at Gölbasi campus of 
Ankara University. This facility will give an opportunity 
to the scientists and industry to use FEL in research and 
development in Turkey and our region. In this study, the 
results of optimization studies and present plans about 
construction process of the facility are presented. 
OVERVIEW OF THE TAC IR FEL 
OSCILLATOR FACILITY PROPOSAL 
The TAC IR FEL project [1] aims to obtain FEL 
between 2-250 microns range using 15-40 MeV energy 
range electron beam. In order to have wide research area, 
it is requested to have cw electron beam with high 
average current as well as pulsed beam with low current. 
Therefore, it is planned to use high average current 
thermionic DC gun and superconducting accelerators with 
IOT power sources. The electron beam parameters are 
given in Table 1. To obtain FEL in 2-250 microns range, 
it was decided to use 2.5 cm and 9 cm period length 
undulators located in two different optical resonators [2]. 
The layout of the IR FEL & Bremsstrahlung laboratory is 
shown in Fig. 1, and the schematic plan of the facility 
building & Accelerator Technologies Institute (ATI) is 
shown in Fig. 2. 
 
 
 
 
 
 
 
 
 
 
 
Figure 1: Layout of the TAC IR FEL & Bremss. lab. 
 
 
 
 
 
Figure 2: Schematic plan of the facility & ATI @ Ankara 
 THE ELECTRON SOURCE & LINAC 
An 300 keV high current thermionic DC gun was 
planned to drive the linac [3]. Schematic view of the 
injector system is shown in Fig. 3. On the other hand, Fig. 
4 represents a detailed view of the gun and the time 
structure of the electron beam. Furthermore, the electron 
linac will consist of two sequenced modules, each 
housing two nine-cell superconducting TESLA cavities 
for cw operation. 
 
 
 
Figure 3: Schematic view of the injector system 
 
 
 
 
Figure 4: Detailed schematic view of thermionic DC gun 
& beam time structure 
 ___________________________________________  
*Work is supported by Turkish State Planning Organization  
#bketen@eng.ankara.edu.tr 
 
Table 1: Electron Beam Parameters 
Electron Beam Value 
Beam energy (MeV) 15-40 
Average current (mA) 1.6 
Repetition rate (MHz) 260*- 26 - 13 
Bunch length (ps) 1-10 
Norm. rms transerve emittance (mm.mrad)  < 15 
Norm. rms longitudinal emittance (keV.ps) < 100 
Macropulse length & repetition cw / tunable 
*For Bremsstrahlung applications 
 
Research Instruments GmbH offers such accelerating 
modules with two superconducting TESLA RF cavities 
for cw operation [4,5]. This module is compact and 
houses two nine-cell TESLA RF cavities and designed for 
cw operation at accelerating fields in the range of 10-15 
MV/m (see Fig. 5). The cryostat of the module has been 
developed by ELBE group [6,8]. For cw operation, two 
SRF ELBE modules were planned to be used in order to 
achieve the beam energy up to 40 MeV [2]. And a 
chicane will be located between the modules. In order to 
obtain 1.6 mA average beam current at 10 MV/m 
gradient, an 16 kW RF power is required. Tests of ELBE 
modules are still being continued with higher power than 
10 kW. [7]. The schematic view of the main accelerating 
section is shown in Fig. 6.  
 
 
 
Figure 5: ACCEL (Research Instruments GmbH) module 
housing two superconducting nine-cell TESLA RF 
cavities [8]. 
 
 
 
 
Figure 6: Main accelerating section of the TAC IR FEL 
oscillator facility. 
THE OPTICAL CAVITIES & 
UNDULATORS 
In order to reduce length of dispersive sections and 
therefore emittance growth due to single bending magnet, 
it was planned to inject the beam into the undulators with 
22.5 degrees bending, as shown in Fig. 1. In addition, the 
magnet material choice for the undulators may probably 
be SmCo or NbFe. On the other hand, single pass gain 
variation versus electron beam energy and K parameter 
for U25 (left) and U90 (right) undulators [3], are shown in 
Fig. 7. 
  
 
 
Figure 7: Single pass gain vs Ee(MeV) & K for U25 (left) 
and U90 (right) @ 120 pC bunch charge and 1 ps bunch 
length  
 
The optical cavity and undulator parameters are given 
in Table 2. And also, expected wavelength range for U25 
and U90 is shown in Fig. 8. It is possible to obtain FEL 
between 2.5 - 250 μm ranges without taking into account 
the nonlinear effects.  
 
 
 
Figure 8: Obtainable wavelength ranges (µm) vs Ee(MeV) 
& K for U25 (left) and U90 (right) 
  
FELO software [9], a one-dimensional free electron 
laser oscillator simulation code developed by ASTeC 
CCLRC Daresbury laboratory, was used for FEL 
optimizations.   
 
 
 
Table 2: TAC IR FEL optical cavity and undulator 
parameters 
Parameter Resonator-1 Resonator-2 
Magnet material SmCo SmCo 
Period length (mm) 25 90 
Number of periods 60 40 
Magnet dimensions (mm) 74x26x10.5 90x90x35 
Steel pole dimensions (mm) 74x18x2 70x20x10 
Magnetic gap (mm) 15 40 
Effective field (T) 0.3591 0.4205 
Krms 0.71 2.5 
Optical cavity length (m) 11.53 11.53 
Resonator type Symm. conc. Symm. conc. 
1st mirror, rad. of curv. (m) 5.86 6.32 
2nd mirror, rad. of curv. (m) 5.86 6.32 
Rayleigh length, ZR (m) 0.75 1.8 
Mirror material Au / Cu Au / Cu 
Rad. of out coup. hole (mm) 01 / 02 / 09 2 / 3 / 4 
Type of  waveguide Not determin. Not determin. 
   
Some of the FEL optimizations are given in figures 
below. Firstly, FEL gain and power vs number of passes 
for seperate wavelengths obtained from U25 & U90 
undulators, are shown in Fig. 9 and Fig.10 respectively.  
 
 
 
Figure 9: Gain vs number of passes  
 
 
 
Figure 10: Intracavity power [MW] vs number of passes 
Figure 11 shows laser pulse energy variation vs number 
of passes for seperate wavelengths obtained from U25 & 
U90 undulators. 
 
 
 
Figure 11: Pulse energy [µJ] vs number of passes 
 
CONCLUSION 
The TAC IR FEL facility [1] will be the first 
accelerator based light source in Turkey. Thereby, 
Turkish scientists and researchers will become acquainted 
with accelerator technologies & light sources based on 
them. With no doubt, TAC IR FEL will provide new 
research opportunities in basic and applied sciences.  
ACKNOWLEDGEMENT 
The authors would like to thank to all the contributors 
for this study on behalf of the TAC Project. And also, 
special thanks to the Turkish State Planning Organization 
(SPO) for supporting the TAC project and to the staff for 
their complete assistance. In addition, thanks a lot to 
ELBE staff, Forschungszentrum Dresden-Rossendorf [6]. 
REFERENCES 
[1]  http://thm.ankara.edu.tr   
[2] A. Aksoy, Ö. Karslı and Ö. Yavaş, The Turkish 
accelerator complex IR FEL project, Infrared Physics 
& Technology, 51 (2008), 378-381.  
[3]  A. Aksoy, Ö. Karslı, B. Ketenoğlu, Ö. Yavaş, A.K. 
Çiftçi, Z. Nergiz and E. Kasap, The status of TAC 
Infrared Free Electron Laser (IR-FEL) Facility, 
Proceedings of EPAC08. 
[4]  http://www.research-instruments.de/ 
[5] P. Stein, et.al. , Fabrication and Installation of 
Superconducting Accelerator Modules for The ERL 
Prototype (ERLP) at Daresbury, EPAC06, p:178. 
[6]  http://www.fzd.de/ 
[7] H. Büttig, et.al. , First Test of a Turnkey 1.3 GHz 30 
kW IOT - Based Power Amplifier at ELBE, Linear 
Acc. Conf., 2009. 
[8] F. Gabriel et.al. , Radiation source ELBE Design 
Report, 1998. 
[9]  http://www.astec.ac.uk/