TY  - CONF
AU  - Vasović, Nikola
AU  - Duane, Russell
AU  - Ristić, Goran
AU  - Stanković, Srboljub
PY  - 2023
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/12122
AB  - An improved RADFET based module dosemeter has been developed by Varadis (a spin out company of Tyndall National Institute in Cork, Ireland) with serial number RM-VT01-A. The module is based on commercially available, commercial-off-the-shelf (COTS) parts and represents an updated version of its predecessor RM-VT01 with an upper dose limit of 10Gy (1 kRad) also based on COTS parts. The RM-VT01-A module was tested to a total dose of 1kGy (100 kRad) in Co60 field at Vinča Institute of Nuclear Sciences, Belgrade, Serbia. The improved module circuit was specifically designed to address the challenge of withstanding 1 kGy (100 kRad) received dose. The primary goal of this poster is to present the improvements in the circuit design and working principle. For this purpose, eleven modules were tested, 8 powered and 3 unpowered during irradiation. The module electronics accommodates both irradiation “sense” and readout “single-current-point” mode, outputting the RADFET threshold voltage (VT) as a dosimetric information, directly proportional to the absorbed dose. The output voltage of the module was measured with a simple benchtop voltmeter to demonstrate module operation simplicity and easy system integrability. The experimental data results showed excellent agreement with the dosimetry system used at the Vinca irradiation facility, and calibration data of the VT01 RadFET part.
PB  - Niš : Faculty of Electronic Engineering
C3  - ELICSIR Project Symposium : Book of abstracts
T1  - An improved RADFET-based module with an extended dose range of 1 kGy TID based on COTS parts
SP  - 49
EP  - 49
UR  - https://hdl.handle.net/21.15107/rcub_vinar_12122
ER  - 

@conference{
author = "Vasović, Nikola and Duane, Russell and Ristić, Goran and Stanković, Srboljub",
year = "2023",
abstract = "An improved RADFET based module dosemeter has been developed by Varadis (a spin out company of Tyndall National Institute in Cork, Ireland) with serial number RM-VT01-A. The module is based on commercially available, commercial-off-the-shelf (COTS) parts and represents an updated version of its predecessor RM-VT01 with an upper dose limit of 10Gy (1 kRad) also based on COTS parts. The RM-VT01-A module was tested to a total dose of 1kGy (100 kRad) in Co60 field at Vinča Institute of Nuclear Sciences, Belgrade, Serbia. The improved module circuit was specifically designed to address the challenge of withstanding 1 kGy (100 kRad) received dose. The primary goal of this poster is to present the improvements in the circuit design and working principle. For this purpose, eleven modules were tested, 8 powered and 3 unpowered during irradiation. The module electronics accommodates both irradiation “sense” and readout “single-current-point” mode, outputting the RADFET threshold voltage (VT) as a dosimetric information, directly proportional to the absorbed dose. The output voltage of the module was measured with a simple benchtop voltmeter to demonstrate module operation simplicity and easy system integrability. The experimental data results showed excellent agreement with the dosimetry system used at the Vinca irradiation facility, and calibration data of the VT01 RadFET part.",
publisher = "Niš : Faculty of Electronic Engineering",
journal = "ELICSIR Project Symposium : Book of abstracts",
title = "An improved RADFET-based module with an extended dose range of 1 kGy TID based on COTS parts",
pages = "49-49",
url = "https://hdl.handle.net/21.15107/rcub_vinar_12122"
}

Vasović, N., Duane, R., Ristić, G.,& Stanković, S.. (2023). An improved RADFET-based module with an extended dose range of 1 kGy TID based on COTS parts. in ELICSIR Project Symposium : Book of abstracts
Niš : Faculty of Electronic Engineering., 49-49.
https://hdl.handle.net/21.15107/rcub_vinar_12122

Vasović N, Duane R, Ristić G, Stanković S. An improved RADFET-based module with an extended dose range of 1 kGy TID based on COTS parts. in ELICSIR Project Symposium : Book of abstracts. 2023;:49-49.
https://hdl.handle.net/21.15107/rcub_vinar_12122 .

Vasović, Nikola, Duane, Russell, Ristić, Goran, Stanković, Srboljub, "An improved RADFET-based module with an extended dose range of 1 kGy TID based on COTS parts" in ELICSIR Project Symposium : Book of abstracts (2023):49-49,
https://hdl.handle.net/21.15107/rcub_vinar_12122 .

TY  - CONF
AU  - Ilić, Stefan D.
AU  - Anđelković, Marko
AU  - Carvajal, Miguel Ángel
AU  - Duane, Russell
AU  - Sarajlić, Milija
AU  - Stanković, Srboljub
AU  - Ristić, Goran
PY  - 2022
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/11117
AB  - Introduction. The approach to increase the sensitivity of semiconductor radiation dosimeter with a stacked design was presented for the thick oxide pMOS transistors, also known as RadFETs (A. Kelleher et al., IEEE transactions on nuclear science 42, 1995). The sensitivity is increasing with the number of RadFETs in stacked structure, but there were limitations because of the diode reverse breakdown voltage during readout current (B. O’Connell et al., In Proceedings of the Third European Conference on Radiation and its Effects on Components and Systems, 1995). Further improvement of the stacked RadFETs device enables detecting a minimum absorbed dose of less than 50 Gy for a 20 V power supply (B. O’Connell et al., Fifth European Conference on Radiation and Its Effects on Components and Systems, 1999). Floating gate MOSFET is a modified structure of MOSFET with another polysilicon gate surrounded by oxide. The advantages of the floating gate MOSFET as a radiation dosimeter are that it does not require thick oxide fabrication and the highest sensitivity is for the zero-bias at the control gate during irradiation (S. Ilić et al., Sensors 20 (11), 2020). Experimental setup. Commercial floating gate MOSFETs designed by Advanced Linear Devices Inc. were used in this paper. Four transistors were connected in the stacked structure (drain and control gate are shorted and connected to the source of the next stacked transistor), and their threshold voltage drift values were measured before and after each irradiation portion with the same conditions. The experiment was performed at the Institute of Nuclear Sciences “Vinča”, Belgrade, Serbia. Radiation source Co-60 was used for irradiation of the components, with the following portions of the absorbed dose (Si): 10 Gy, 10 Gy, 10 Gy, 20 Gy, 50 Gy, 400 Gy, 500 Gy, 4 mGy, 45 mGy, 50 mGy, respectively (absorbed dose was 100 mGy in total). All measurements were performed in a test fixture with triax cables by Keithley 2636A Source Measure Unit. During irradiation, all stacked transistors were zero-biased. Results. Observing the threshold voltage drift of the four stacked floating gate MOS transistors, we noticed that the stack of two transistors has the most stable reading values over time (smallest drift). Considering this, we analyzed only two stacked floating gate MOS transistors as a passive dosimeter for the low doses. The results show that it is possible to detect the first portion of 10 Gy at which the sensitivity of the two stacked transistors is 23 V/Gy. For the next same portion, the sensitivity is 17 V/Gy, while for the third, the value is 7 V/Gy. However, for the next 20 Gy, there is a tiny shift, and the sensitivity is only 1 V/Gy. Decreased sensitivity with absorbed dose is a feature of the floating gate MOSFET that has been observed before for much higher doses (S. Ilić et al., Sensors 20 (11), 2020). There is a large overlap in the threshold voltage drift values for the next four radiation portions. However, for the last two largest portions, 45 and 50 mGy, there is a significant threshold voltage shift with no overlapping, and thus it is possible to determine the sensitivity of 0.0226 and 0.0214 V/Gy, respectively. Conclusions. Using a floating gate MOSFET as a low-dose passive dosimeter is possible, but recharging the floating gate and reusing this device for higher total ionizing doses should be investigated.
PB  - RAD Centre, Niš, Serbia
C3  - RAD 2022 : 10th Jubilee International Conference on Radiation in Various Fields of Research : book of abstracts; June 13-17; Herceg Novi, Montenegro
T1  - Stacked floating gate MOSFET as a passive dosimeter
SP  - 113
DO  - 10.21175/rad.spr.abstr.book.2022.26.12
ER  - 

@conference{
author = "Ilić, Stefan D. and Anđelković, Marko and Carvajal, Miguel Ángel and Duane, Russell and Sarajlić, Milija and Stanković, Srboljub and Ristić, Goran",
year = "2022",
abstract = "Introduction. The approach to increase the sensitivity of semiconductor radiation dosimeter with a stacked design was presented for the thick oxide pMOS transistors, also known as RadFETs (A. Kelleher et al., IEEE transactions on nuclear science 42, 1995). The sensitivity is increasing with the number of RadFETs in stacked structure, but there were limitations because of the diode reverse breakdown voltage during readout current (B. O’Connell et al., In Proceedings of the Third European Conference on Radiation and its Effects on Components and Systems, 1995). Further improvement of the stacked RadFETs device enables detecting a minimum absorbed dose of less than 50 Gy for a 20 V power supply (B. O’Connell et al., Fifth European Conference on Radiation and Its Effects on Components and Systems, 1999). Floating gate MOSFET is a modified structure of MOSFET with another polysilicon gate surrounded by oxide. The advantages of the floating gate MOSFET as a radiation dosimeter are that it does not require thick oxide fabrication and the highest sensitivity is for the zero-bias at the control gate during irradiation (S. Ilić et al., Sensors 20 (11), 2020). Experimental setup. Commercial floating gate MOSFETs designed by Advanced Linear Devices Inc. were used in this paper. Four transistors were connected in the stacked structure (drain and control gate are shorted and connected to the source of the next stacked transistor), and their threshold voltage drift values were measured before and after each irradiation portion with the same conditions. The experiment was performed at the Institute of Nuclear Sciences “Vinča”, Belgrade, Serbia. Radiation source Co-60 was used for irradiation of the components, with the following portions of the absorbed dose (Si): 10 Gy, 10 Gy, 10 Gy, 20 Gy, 50 Gy, 400 Gy, 500 Gy, 4 mGy, 45 mGy, 50 mGy, respectively (absorbed dose was 100 mGy in total). All measurements were performed in a test fixture with triax cables by Keithley 2636A Source Measure Unit. During irradiation, all stacked transistors were zero-biased. Results. Observing the threshold voltage drift of the four stacked floating gate MOS transistors, we noticed that the stack of two transistors has the most stable reading values over time (smallest drift). Considering this, we analyzed only two stacked floating gate MOS transistors as a passive dosimeter for the low doses. The results show that it is possible to detect the first portion of 10 Gy at which the sensitivity of the two stacked transistors is 23 V/Gy. For the next same portion, the sensitivity is 17 V/Gy, while for the third, the value is 7 V/Gy. However, for the next 20 Gy, there is a tiny shift, and the sensitivity is only 1 V/Gy. Decreased sensitivity with absorbed dose is a feature of the floating gate MOSFET that has been observed before for much higher doses (S. Ilić et al., Sensors 20 (11), 2020). There is a large overlap in the threshold voltage drift values for the next four radiation portions. However, for the last two largest portions, 45 and 50 mGy, there is a significant threshold voltage shift with no overlapping, and thus it is possible to determine the sensitivity of 0.0226 and 0.0214 V/Gy, respectively. Conclusions. Using a floating gate MOSFET as a low-dose passive dosimeter is possible, but recharging the floating gate and reusing this device for higher total ionizing doses should be investigated.",
publisher = "RAD Centre, Niš, Serbia",
journal = "RAD 2022 : 10th Jubilee International Conference on Radiation in Various Fields of Research : book of abstracts; June 13-17; Herceg Novi, Montenegro",
title = "Stacked floating gate MOSFET as a passive dosimeter",
pages = "113",
doi = "10.21175/rad.spr.abstr.book.2022.26.12"
}

Ilić, S. D., Anđelković, M., Carvajal, M. Á., Duane, R., Sarajlić, M., Stanković, S.,& Ristić, G.. (2022). Stacked floating gate MOSFET as a passive dosimeter. in RAD 2022 : 10th Jubilee International Conference on Radiation in Various Fields of Research : book of abstracts; June 13-17; Herceg Novi, Montenegro
RAD Centre, Niš, Serbia., 113.
https://doi.org/10.21175/rad.spr.abstr.book.2022.26.12

Ilić SD, Anđelković M, Carvajal MÁ, Duane R, Sarajlić M, Stanković S, Ristić G. Stacked floating gate MOSFET as a passive dosimeter. in RAD 2022 : 10th Jubilee International Conference on Radiation in Various Fields of Research : book of abstracts; June 13-17; Herceg Novi, Montenegro. 2022;:113.
doi:10.21175/rad.spr.abstr.book.2022.26.12 .

Ilić, Stefan D., Anđelković, Marko, Carvajal, Miguel Ángel, Duane, Russell, Sarajlić, Milija, Stanković, Srboljub, Ristić, Goran, "Stacked floating gate MOSFET as a passive dosimeter" in RAD 2022 : 10th Jubilee International Conference on Radiation in Various Fields of Research : book of abstracts; June 13-17; Herceg Novi, Montenegro (2022):113,
https://doi.org/10.21175/rad.spr.abstr.book.2022.26.12 . .

TY  - CONF
AU  - Carvajal, Miguel
AU  - Sarajlić, Milija
AU  - Stanković, Srboljub
AU  - Vasiljević-Radović, Dana
AU  - Ristić, Goran
PY  - 2022
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/12121
AB  - The energy that comes from the source of ionizing radiation is enormous and quite
unused. Using energy from ionizing radiation is a novel concept, while so far in the
literature (to the best of our knowledge), only beta radiation has been treated as a
possible source of energy (Quenon 2021). This paper focuses on utilizing gamma
radiation energy using the Cobalt-60 radiation source. Direct conversion of radiation into electrical energy is possible using pn or pin junction-based semiconductor
structures. When high-energy photons hit a semiconductor structure, a built-in
electric field of pn junction can separate the generated electron-hole pairs before
they recombine, creating the potential difference at the component electrodes. The
PIN diodes used in this paper were made in planar technology, with three different
active area surfaces: 0.8, 5 and 80 mm2
, at the Center of Microelectronic Technologies, Institute of Chemistry, Technology and Metallurgy, University of Belgrade,
Serbia. The experiment was conducted in controlled laboratory conditions at the
Department of Radiation and Environmental Protection at the Vinča Institute of
Nuclear Sciences, Belgrade, Serbia. The range of gamma radiation dose rates for
which the PIN diodes have been tested is from 1 µGy/h to 10 Gy/h under controlled
conditions at room temperature. It is necessary for the diode to operate in a photovoltaic mode to act as a current source in an electrical circuit. Therefore, during irradiation, the characteristics of diodes: short-circuit current and open-circuit voltage
were measured as the most important parameters of the current source. The lowest
detected dose rate value of the PIN diode with the largest active area (80 mm2
) was
5 mGy/h, while diodes with middle (5 mm2
) and the smallest active area (0.8 mm2
)
were 100 mGy/h. The short-circuit current values of PIN diodes for all active area dimensions have a linear dependence with a given dose rate range. By calculating the
short-circuit current density, we obtain that diodes with different active areas have
almost the same dependence on the dose rate. This result indicates that the current
generated under the ionizing radiation directly depends on the size of the active
region of the PIN diode. On the other hand, open-circuit voltage values do not have
a linear dependence on the dose rate, even the diode with the smallest active area
(0.8 mm2
) has higher values than the diode with the middle active area (5 mm2
).
For the highest dose rate (10 Gy/h), the short-circuit current value of the PIN diode
with the largest active area is 37 nA, and the open-circuit voltage is 118 mV, which
can enable power supply of the low power electric circuits by connecting diodes in
series and parallel. The research should continue in order to develop a self-powered
circuit that will monitor radioactive sources and their environment.
C3  - BPU11 : 11th International Conference of the Balkan Physical Union
T1  - Direct Conversion Of Ionizing Radiation Into Electrical Energy Using PIN Diodes
VL  - 427
SP  - 213
EP  - 214
UR  - https://hdl.handle.net/21.15107/rcub_vinar_12121
ER  - 

@conference{
author = "Carvajal, Miguel and Sarajlić, Milija and Stanković, Srboljub and Vasiljević-Radović, Dana and Ristić, Goran",
year = "2022",
abstract = "The energy that comes from the source of ionizing radiation is enormous and quite
unused. Using energy from ionizing radiation is a novel concept, while so far in the
literature (to the best of our knowledge), only beta radiation has been treated as a
possible source of energy (Quenon 2021). This paper focuses on utilizing gamma
radiation energy using the Cobalt-60 radiation source. Direct conversion of radiation into electrical energy is possible using pn or pin junction-based semiconductor
structures. When high-energy photons hit a semiconductor structure, a built-in
electric field of pn junction can separate the generated electron-hole pairs before
they recombine, creating the potential difference at the component electrodes. The
PIN diodes used in this paper were made in planar technology, with three different
active area surfaces: 0.8, 5 and 80 mm2
, at the Center of Microelectronic Technologies, Institute of Chemistry, Technology and Metallurgy, University of Belgrade,
Serbia. The experiment was conducted in controlled laboratory conditions at the
Department of Radiation and Environmental Protection at the Vinča Institute of
Nuclear Sciences, Belgrade, Serbia. The range of gamma radiation dose rates for
which the PIN diodes have been tested is from 1 µGy/h to 10 Gy/h under controlled
conditions at room temperature. It is necessary for the diode to operate in a photovoltaic mode to act as a current source in an electrical circuit. Therefore, during irradiation, the characteristics of diodes: short-circuit current and open-circuit voltage
were measured as the most important parameters of the current source. The lowest
detected dose rate value of the PIN diode with the largest active area (80 mm2
) was
5 mGy/h, while diodes with middle (5 mm2
) and the smallest active area (0.8 mm2
)
were 100 mGy/h. The short-circuit current values of PIN diodes for all active area dimensions have a linear dependence with a given dose rate range. By calculating the
short-circuit current density, we obtain that diodes with different active areas have
almost the same dependence on the dose rate. This result indicates that the current
generated under the ionizing radiation directly depends on the size of the active
region of the PIN diode. On the other hand, open-circuit voltage values do not have
a linear dependence on the dose rate, even the diode with the smallest active area
(0.8 mm2
) has higher values than the diode with the middle active area (5 mm2
).
For the highest dose rate (10 Gy/h), the short-circuit current value of the PIN diode
with the largest active area is 37 nA, and the open-circuit voltage is 118 mV, which
can enable power supply of the low power electric circuits by connecting diodes in
series and parallel. The research should continue in order to develop a self-powered
circuit that will monitor radioactive sources and their environment.",
journal = "BPU11 : 11th International Conference of the Balkan Physical Union",
title = "Direct Conversion Of Ionizing Radiation Into Electrical Energy Using PIN Diodes",
volume = "427",
pages = "213-214",
url = "https://hdl.handle.net/21.15107/rcub_vinar_12121"
}

Carvajal, M., Sarajlić, M., Stanković, S., Vasiljević-Radović, D.,& Ristić, G.. (2022). Direct Conversion Of Ionizing Radiation Into Electrical Energy Using PIN Diodes. in BPU11 : 11th International Conference of the Balkan Physical Union, 427, 213-214.
https://hdl.handle.net/21.15107/rcub_vinar_12121

Carvajal M, Sarajlić M, Stanković S, Vasiljević-Radović D, Ristić G. Direct Conversion Of Ionizing Radiation Into Electrical Energy Using PIN Diodes. in BPU11 : 11th International Conference of the Balkan Physical Union. 2022;427:213-214.
https://hdl.handle.net/21.15107/rcub_vinar_12121 .

Carvajal, Miguel, Sarajlić, Milija, Stanković, Srboljub, Vasiljević-Radović, Dana, Ristić, Goran, "Direct Conversion Of Ionizing Radiation Into Electrical Energy Using PIN Diodes" in BPU11 : 11th International Conference of the Balkan Physical Union, 427 (2022):213-214,
https://hdl.handle.net/21.15107/rcub_vinar_12121 .

TY  - JOUR
AU  - Ilić, Stefan
AU  - Jevtić, Aleksandar
AU  - Stanković, Srboljub
AU  - Ristić, Goran
PY  - 2020
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/9053
AB  - This paper describes the possibility of using an Electrically Programmable Analog Device (EPAD) as a gamma radiation sensor. Zero-biased EPAD has the lowest fading and the highest sensitivity in the 300 Gy dose range. Dynamic bias of the control gate during irradiation was presented for the first time; this method achieved higher sensitivity compared to static-biased EPADs and better linear dependence. Due to the degradation of the transfer characteristics of EPAD during irradiation, a function of the safe operation area has been found that determines the maximum voltage at the control gate for the desired dose, which will not lead to degradation of the transistor. Using an energy band diagram, it was explained why the zero-biased EPAD has higher sensitivity than the static-biased EPAD.
T2  - Sensors
T1  - Floating-Gate MOS Transistor with Dynamic Biasing as a Radiation Sensor
VL  - 20
IS  - 11
SP  - 3329
DO  - 10.3390/s20113329
ER  - 

@article{
author = "Ilić, Stefan and Jevtić, Aleksandar and Stanković, Srboljub and Ristić, Goran",
year = "2020",
abstract = "This paper describes the possibility of using an Electrically Programmable Analog Device (EPAD) as a gamma radiation sensor. Zero-biased EPAD has the lowest fading and the highest sensitivity in the 300 Gy dose range. Dynamic bias of the control gate during irradiation was presented for the first time; this method achieved higher sensitivity compared to static-biased EPADs and better linear dependence. Due to the degradation of the transfer characteristics of EPAD during irradiation, a function of the safe operation area has been found that determines the maximum voltage at the control gate for the desired dose, which will not lead to degradation of the transistor. Using an energy band diagram, it was explained why the zero-biased EPAD has higher sensitivity than the static-biased EPAD.",
journal = "Sensors",
title = "Floating-Gate MOS Transistor with Dynamic Biasing as a Radiation Sensor",
volume = "20",
number = "11",
pages = "3329",
doi = "10.3390/s20113329"
}

Ilić, S., Jevtić, A., Stanković, S.,& Ristić, G.. (2020). Floating-Gate MOS Transistor with Dynamic Biasing as a Radiation Sensor. in Sensors, 20(11), 3329.
https://doi.org/10.3390/s20113329

Ilić S, Jevtić A, Stanković S, Ristić G. Floating-Gate MOS Transistor with Dynamic Biasing as a Radiation Sensor. in Sensors. 2020;20(11):3329.
doi:10.3390/s20113329 .

Ilić, Stefan, Jevtić, Aleksandar, Stanković, Srboljub, Ristić, Goran, "Floating-Gate MOS Transistor with Dynamic Biasing as a Radiation Sensor" in Sensors, 20, no. 11 (2020):3329,
https://doi.org/10.3390/s20113329 . .

TY  - CONF
AU  - Jakšić, Aleksandar
AU  - Vasović, Nikola
AU  - Duane, Russell
AU  - Stanković, Srboljub
AU  - Martinez-Garcia, Maria Sofia
AU  - Palma, Alberto
AU  - Ristić, Goran
PY  - 2017
UR  - https://vinar.vin.bg.ac.rs/handle/123456789/11196
PB  - RAD Association, Niš, Serbia
C3  - RAD 2017 : 5th International Conference on Radiation in Various Fields of Research : book of abstracts; June 12-16, 2017; Budva, Montenegro
T1  - Radiation Response of Two Types of Commercial RADFETs
SP  - 179
UR  - https://hdl.handle.net/21.15107/rcub_vinar_11196
ER  - 

@conference{
author = "Jakšić, Aleksandar and Vasović, Nikola and Duane, Russell and Stanković, Srboljub and Martinez-Garcia, Maria Sofia and Palma, Alberto and Ristić, Goran",
year = "2017",
publisher = "RAD Association, Niš, Serbia",
journal = "RAD 2017 : 5th International Conference on Radiation in Various Fields of Research : book of abstracts; June 12-16, 2017; Budva, Montenegro",
title = "Radiation Response of Two Types of Commercial RADFETs",
pages = "179",
url = "https://hdl.handle.net/21.15107/rcub_vinar_11196"
}

Jakšić, A., Vasović, N., Duane, R., Stanković, S., Martinez-Garcia, M. S., Palma, A.,& Ristić, G.. (2017). Radiation Response of Two Types of Commercial RADFETs. in RAD 2017 : 5th International Conference on Radiation in Various Fields of Research : book of abstracts; June 12-16, 2017; Budva, Montenegro
RAD Association, Niš, Serbia., 179.
https://hdl.handle.net/21.15107/rcub_vinar_11196

Jakšić A, Vasović N, Duane R, Stanković S, Martinez-Garcia MS, Palma A, Ristić G. Radiation Response of Two Types of Commercial RADFETs. in RAD 2017 : 5th International Conference on Radiation in Various Fields of Research : book of abstracts; June 12-16, 2017; Budva, Montenegro. 2017;:179.
https://hdl.handle.net/21.15107/rcub_vinar_11196 .

Jakšić, Aleksandar, Vasović, Nikola, Duane, Russell, Stanković, Srboljub, Martinez-Garcia, Maria Sofia, Palma, Alberto, Ristić, Goran, "Radiation Response of Two Types of Commercial RADFETs" in RAD 2017 : 5th International Conference on Radiation in Various Fields of Research : book of abstracts; June 12-16, 2017; Budva, Montenegro (2017):179,
https://hdl.handle.net/21.15107/rcub_vinar_11196 .