Abstract
This paper aims to evaluate a groundbreaking bio-TFET that utilizes the fringe fields capacitance concept to detect neutral and charged biomolecules. While facilitating fabrication process and scalability, this innovative bio-TFET is able to rival the conventional bio-TFET which relies on carving cavities in the gate oxide. The cavities of the proposed device are carved in the spacers over the source region and in the vicinity of the gate metal. Inserting biomolecules in the cavities of our bio-TFET modifies the fringe fields arising out of the gate metal. As a result, these spacers modulate tunneling barrier width at the source-channel tunneling junction. We have assessed our proposed device’s DC/RF performance using the calibrated Silvaco ATLAS device simulator. For further evaluation of the reliability of our bio-TFET, non-idealities, such as trap-assisted tunneling and temperature, are also studied. The device we propose is highly suitable for biosensing applications, as evidenced by the parameters of \({S}_{{I}_{ds}}\) = 1.21 × 103, SSS = 0.365, and \({S}_{{f}_{T}}\) = 1.63 × 103 at VGS = 1 V.
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Introduction
The demand for high-performance biosensors which can detect various diseases in their early stages is rapidly increasing. Label detection-based biosensors fall short of sensitivity and can alter the intrinsic characteristics of biomolecules1,2. In contrast, dielectric-modulated label-free biosensors preserve natural characteristics of biomolecules3. The ion-sensitive field effect transistor (ISFET) was the first label-free biosensor based on FETs, but it could only detect charged biomolecules4. To address this limitation, researchers developed the dielectric-modulated field-effect transistor (DMFET) to detect charged and neutral biomolecules5. The DMFET contains cavities carved in the gate metal or gate oxide of a MOSFET, where the entrance of biomolecules changes the electrostatic control of the gate, leading to the change in different device’s electronic characteristics. However, shrinking the dimensions of MOSFETs into the nanometer regime causes crucial problems for biosensing applications of DMFETs6.
Tunneling field-effect transistors (TFETs) are being considered as a potential alternative to short-channel MOSFETs. Unlike MOSFETs, TFETs regulate subthreshold swing through electrostatic control of the gate. TFETs also benefit from band pass filtering of high-energy electrons in the source region, leading to a much lower off-state current than that of MOSFETs7. Furthermore, the TFETs’ major limitations, such as low on-state current and ambipolar conduction, have been effectively addressed (see8,9,10,11,12,13,14).
Several TFET-based biosensors with various geometry have been proposed. Some of the most interesting introduced devices are double-gate15,16, vertical17,18,19,20, core-shell nanotube21,22,23, charge-plasma24,25,26,27,28, and electron–hole bilayer29 TFET structures. However, in all of these devices, the gate leakage current can affect the performance of the biosensor. To address this issue, some researchers have suggested using a low-thickness sacrificial layer between the gate and channel regions30, but this approach can create challenges during the fabrication process.
This paper suggests a novel double-gate biosensor in which two cavities are carved over the source region. With applying the gate voltage, fringe fields in the spacers modify the strength of the electric field at the source-channel junction, resulting in considerable variations in the energy barrier width of the tunneling window. By employing a low-defect Si-SiO2 interface as the semiconductor-oxide junction, our proposed bioTFET not only benefits from full compatibility with CMOS technology but also ensures high reliability. Moreover, the fabrication process is less arduous compared to bio-TFETs that rely on nanowires or nanotubes configurations. Additionally, the non-etched gate oxide and asymmetric doping eliminates leakage current and ambipolar conduction, respectively.
Device structure, fabrication process, and simulation methodology
A schematic two dimensional view of our designed bio-sensor (named FFC-bioTFET) is shown in Fig. 1. To have the most compatibility with CMOS technology conventional Si-SiO2 structure is employed. In this device the source, channel, and drain regions are doped with the impurity concentrations of 1 × 1019 cm−3, 1 × 1017 cm−3, and 3 × 1018 cm−3, respectively. In order to convert the double-gate TFET into a biosensor, two cavities measuring 20 nm × 7 nm are created in the source side spacers. Compared to the conventional DMFET biosensors which need a sacrificial layer to prevent gate-leakage current, in our bioTFET no such a layer is necessary. Reducing fabrication challenges is another benefit of carving cavities in the spacer regions. To prevent direct source-to-drain tunneling, we used a 50 nm channel between the source and drain. Metal gates, with a work function of 4 eV, modulate the energy bands at the tunneling junction. This figure also includes a simple capacitive model of the proposed biosensor at the tunneling junction. It can be inferred from the model that by inserting biomolecules with higher permittivity, which can be modeled by increased Cfr, the electric field across Cj, which models the tunneling junction, reduces and consequently the tunneling rate degrades.
Figure 2 presents a clear and precise fabrication process for FFC-bio TFET. To fabricate the biosensor, two wafers with the same fabrication procedures should be prepared. In the first step, an SOI wafer is created (see Fig. 2a). Then, p+-source and n+-drain are created using two consecutive ion-implantation steps (see Fig. 2b,c). After the deposition of the SiO2 as the spacer, gate metal is deposited (see Fig. 2d,e). In the next step, the cavity is carved in the spacer using the wet-etching technique, followed by removing the buried oxide (See Fig. 2f,g). Then, two wafers are bonded together (see Fig. 2h,i). In the last stage, source and drain contacts are connected (see Fig. 2j).
Our proposed biosensor is simulated by using the Silvaco ATLAS device simulator31, where the following models are activated to generate different device characteristics. The dynamic nonlocal band-to-band tunneling model is enabled to calculate the current at the source-channel tunneling junction. Defects at the semiconductor-oxide interface can deteriorate the performance of TFET-based biosensors, so we have used the Interface model with the Dit = 3 × 1011 cm−2 eV−1 for all simulations32. Since silicon has a large indirect bandgap and channel thickness is 10 nm, subband quantization is not considered. The gate leakage current was not taken into account because 7 nm SiO2 was used as the gate oxide. All other activated models are SRH, auger, BGN, fermi, and CVT. The transfer characteristics of the simulated device is plotted and compared to the extracted values of the Ref.33. The depicted results of Fig. 3 demonstrate a good match, effectively validating the simulation procedure.
Simulation results
In this section, we will analyze how different neutral and charged biomolecules affect the AC/DC performance of FFC-bio TFET. Additionally, we will assess the reliability of our proposed structure under non-ideal conditions, such as temperature variation and trap states. Figure 4 depicts the electric field contours of the device when the cavities are filled by Air, APTES (k = 3.57) and Gelatin (k = 12), respectively. It can be inferred that insertion of biomolecules with higher dielectric constants in the cavities increases the extension of the electric field lines in the source region and consequently smooths the lateral electric field at the tunneling junction which leads to a longer tunneling path for the charge carriers.
Figure 5a illustrates the impact of the dielectric constant of air and biomolecules on the energy bands diagram of FFC-bioTFET along the \(\overline{{\text{AB}} }\) segment (as shown in Fig. 1). We can see that while the modulation of the energy bands in the channel is negligible, biomolecules with higher dielectric constant significantly modulate the band bending in the source region, as a result tunneling barrier width increases. It can be seen that at the VGS = 0.5 V, the value of the energy barrier width for Air and Gelatin is 25.6 nm and 36.3 nm, respectively. With the doubling of gate voltage, the value of the abovementioned parameters decreases to 17.8 nm and 27.1 nm, respectively. In Fig. 5b, the impact of various neutral biomolecules on the transfer characteristics of FFC-bioTFET is depicted. In conventional bio-TFET, biomolecules with higher dielectric constants enhance the band-to-band tunneling rate at the source-channel junction. In FFC-bioTFET, we have an inverse scenario, meaning that with increasing biomolecule’s dielectric constants drain current decreases.
In Fig. 6a, the impact of the biomolecule’s dielectric constant on the drain current sensitivity of our proposed structure is depicted. It is given by \({S}_{{I}_{D}}=\left(\frac{{I}_{ds}^{air}-{I}_{ds}^{bio}}{{I}_{ds}^{bio}}\right)\); here, \({I}_{ds}^{air}\) is the drain current when we use Air in the cavities and is the constant part of the relationship, while the values of \({I}_{ds}^{bio}\) highly depend on the type of biomolecules we use in the cavities. For k = 1.54, we have a \({S}_{{I}_{ds.max}}\) = 0.94, while having Gelatin in the cavities causes this to reach to 1.21 × 103 (which indicates more than three decades increase). The performance of a bio-TFET can be assessed by considering its subthreshold swing (SS) and subthreshold swing sensitivity (SSS), too. Figure 6b shows the impact of various neutral biomolecules on the SS and SSS of FFC-bioTFET. Subthreshold swing sensitivity is defined by \({S}_{SS}=\left|\frac{{SS}_{bio}-{SS}_{air}}{{SS}_{bio}}\right|\), where SSair and SSbio are the minimum gate voltages required for a ten-time increment of the drain current in the presence of Air and biomolecule, respectively. By using Gelatin instead of Uricase (k = 1.54), the value of SS and SSS reaches from 90.23 mV/dec and 0.029 to 137.99 mV/dec and 0.365, respectively. Figure 6c illustrates how the presence of neutral biomolecules affects the threshold voltage and the threshold voltage sensitivity of FFC-bioTFET. To obtain the threshold voltage we employed the maximum transconductance method as a more reliable threshold voltage measure34. We have defined the threshold voltage sensitivity as ΔVth = Vth(air) − Vth(bio), where Vth(air) is the threshold voltage for k = 1, and Vth(bio) is the threshold voltage in the presence of biomolecules in the cavities21.
In addition to excellent sensitivity, a good sensor should exhibit good selectivity. Selectivity is one of the fundamental parameters for a biosensor, and enables biosensor to identify a specific biomolecule in the present of another biomolecule. To have an evaluation about this parameter, we have calculated the selectivity between four pairs of natural biomolecules with the following relationships35,
and the results are depicted in Fig. 6d. It can be observed that FFC-bioTFET reveals more efficient selectivity to detect between APTES and Keratin. This can be attributed to the higher values of Δεk/εk for the aforementioned pair of biomolecules compared to other cases.
In tunneling FETs, when VDS is lower than VGS, raising the drain voltage significantly modulates the tunneling junction, increasing available states for tunneling. Figure 7a shows the impact of VDS variation on the transfer characteristics of FFC-bioTFET for Air and Gelatin. It is evident that raising the VDS leads to a higher on-state current for both cases. Figure 7b shows that with the reduction of VDS, drain current sensitivity increases.
Biosensors based on tunnel transistors can also detect a type of biomolecule that possess charge density known as charged biomolecules, hence, we investigate the impact of a well-known charged biomolecule called deoxyribonucleic acid (DNA) on the DC performance of our proposed biosensor.
In Fig. 8a, the transfer characteristics of FFC-bioTFET for four different charge densities (− 1 × 1012 C.cm−2, − 5 × 1011 C.cm−2, 5 × 1011 C.cm−2, and 1 × 1012 C.cm−2) reveal that the curves with positively charged biomolecules exhibit lower on-state currents when compared to negatively charged ones. Indeed, the positively charged biomolecules have adverse influence on the band bending sharpness at the source-channel tunneling junction. Figure 8b displays the impact of charged biomolecules on the drain current sensitivity of FFC-bioTFET. The drain–current sensitivity of positively charged biomolecules is higher than negatively charged ones since positively charged biomolecules degrade the on-state current more. For DNA biomolecule with Nf = − 1 × 1012 C.cm−2, \({S}_{{I}_{ds}}\) = 52.29, while for Nf = 1 × 1012 C.cm−2, \({S}_{{I}_{ds}}\) with more than one decade increment reaches to 1.09 × 103. In Fig. 8c, it is shown how the charged biomolecules of DNA affect the subthreshold swing (SS) and subthreshold swing sensitivity (SSS) of FFC-bioTFET. The lowest SS is observed for DNA biomolecules with Nf = − 1 × 1012 C.cm−2, while for Nf = 1 × 1012 C.cm−2, this value has a ~ 133% increase. However, the highest SSS is observed for DNA with Nf = 1 × 1012 C.cm−2, as compared to the other three cases.
Linearity is an important factor in highly sensitive biosensors. To evaluate the linearity of a biosensor, the transconductance must be calculated. The equation gm = \(\partial\)ID/\(\partial\)VGS determines this value36. Figure 9a shows that when the value of k changes from 1 to 12, the transconductance decreases due to the effect of higher dielectric constants on the band bending at the tunneling junction. We plotted the transconductance sensitivity as a function of the biomolecule’s dielectric constant in Fig. 9b. It is noticeable that biomolecules with higher values of k result in higher \({S}_{{g}_{m}}\). The parasitic gate-to-source and gate-to-drain capacitances significantly influence the AC performance of FETs. In this section, we have examined how these parameters impact the total gate capacitance (CGG), cut-off frequency (fT), and sensitivity of cut-off frequency (\({S}_{{f}_{T}}\)). Figure 10a shows the variation of the parasitic capacitances of FFC-bioTFET for Air and Gelatin molecules. When k = 12, the value of CGS is slightly higher than when k = 1, since the higher k values increase the extension of fringe field lines. It is worth noting that gate-to-drain capacitance dominates the total gate capacitance for both cases, except when k = 12 and VGS is lower than 0.4 V. In Fig. 10b,c, we see the cut-off frequency and its sensitivity changing as k varies between 1 and 12. The graph in Fig. 10b shows that higher values of k lead to lower fT, mainly because gm decreases (as shown in Fig. 9a). Moreover, higher values of k contribute to the higher values of the total gate capacitance. According to Fig. 10c, \({S}_{{f}_{T}}\) varies as we change the biomolecule. We notice that using Gelatin instead of Uricase significantly increases \({S}_{{f}_{T}}\) by several decades, reaching from 0.97 to 1.63 × 103.
Non-uniform distribution of biomolecules in the biosensor’s cavities may affect the sensitivity of the device. In order to investigate the impact of non-ideal filling of cavities we have considered four different semi-filled profiles with a filling factor of 50% as depicted in Fig. 11. Gelatin biomolecule is considered as the sample in this investigation. Figure 12a demonstrates the impact of unfilled cavities on the transfer characteristics of FFC-bioTFET. It is noticeable that the on-state current in Case (d) surpasses the other cases. In fact, when the low-k spacer is closer to the source-channel junction, the energy bands of the source region are less affected by the fringe fields and consequently the on-state current is higher. Meanwhile, Fig. 12b illustrates that Case (c), in which the permittivity of the gate spacers is higher than that of the other three cases, exhibits the most heightened sensitivity of the drain current.
Trap-assisted tunneling is a detrimental phenomenon which shades a notable impact on the performance of TFETs37. Figure 13a shows that activating this model considerably increases the off-state current of FFC-bioTFET. Figure 13b portrays the impact of TAT on the \({S}_{{I}_{ds}}\) of FFC-bioTFET for k = 12. If the VGS falls below 0.35 V, TAT will cause a reduction in drain current sensitivity. On the other hand, if TAT is not engaged and VGS is above 0.35 V, we can expect higher \({S}_{{I}_{ds}}\) values.
The other non-ideality that may significantly influence the TFETs performance is the impact of interface trap charges (ITCs). It should be emphasized that the oxide–semiconductor interface of our proposed structure is composed of SiO2-Si, which is the most desirable case in terms of interface trap density. In Fig. 14a we have shown that FFC-bioTFET with negative ITC poses the highest onset voltage for k = 1 and k = 12. As a result, the on-state current for Dit = − 3 × 1011 cm−2 eV−1 is lower than those of other cases. On the other hand, the onset of band-to-band tunneling of FFC-bioTFET for Dit = + 3 × 1011 cm−2 eV−1 reduces for both cases. Figure 14b depicts the impact of interface trap charges on the drain current sensitivity of our structure. Similar to Fig. 14a, the positively charged interface of SiO2-Si displays better transduction efficiency for a wider range of gate voltages.
The performance of TFETs in the off-state and subthreshold region is greatly impacted by changes in temperature. In Fig. 15a, we demonstrate the effects of increasing the temperature by 50 K on the transfer characteristics of FFC-bioTFET. Notably, the off-state current experiences a significant increase for both k = 1 and k = 12. Figure 15b depicts how temperature affects the \({S}_{{I}_{ds}}\) of our biosensor. Although the difference between the value of \({S}_{{I}_{ds}}\) for Temp = 300 K and Temp = 350 K is significant for lower values of VGS, the \({S}_{{I}_{ds}}\) remains almost the same for gate voltages higher than 0.8 V.
As we have emphasized above, the significant benefits of our biosensor lie in its scalability and easier fabrication process. However, since the main electric field of the gate affecting the channel is dominant compared to the fringing field, we expected that conventional DMFETs show better sensitivity than that of our proposed biosensor (at least in simulations). Table 1 presents a comparative evaluation of the performance of various dielectric-modulated biosensors, which have been recently reported. In order to prepare this table, we selected the Gelatin biomolecule with a dielectric constant of 12 as the target for our analysis. We focused on comparing the off-state current sensitivity of the biosensors given by \({S}_{{I}_{off}}\left(\%\right)=\left(\frac{{I}_{off}^{bio}-{I}_{off}^{air}}{{I}_{off}^{air}}\right)\times 100\), which is a critical parameter for their performance evaluation41.
Conclusion
We have developed a new type of biosensor that uses the concept of fringe field capacitance. Unlike traditional dielectric-modulated bioTFET, our biosensor has carved cavities in the spacer regions, making gate leakage current no longer a problem. We also depicted that our biosensor is easier to realize and less-challenging to fabricate. We used the Silvaco ATLAS devices simulator to carry out all the numerical simulations. Our evaluation involves assessing the impact of both neutral and charged biomolecules on critical parameters such as drain current sensitivity (\({S}_{{I}_{ds}}\)) and subthreshold swing sensitivity (SSS). Furthermore, we have investigated the impact of less-analyzed non-idealities, such as traps-assisted tunneling and temperature, on the performance of our bioTFET. Our device’s parameters, including \({S}_{{I}_{ds}}\) = 1.21 × 103, SSS = 0.365, and \({S}_{{f}_{T}}\) = 1.63 × 103, demonstrate that it can compete with other TFET-based dielectric-modulated biosensors.
Data availability
The datasets used and/or analyzed during the current study available from the corresponding author on reasonable request.
References
Bras, M. et al. Control of immobilization and hybridization on DNA chips by fluorescence spectroscopy. J. Fluoresc. 10, 247–247. https://doi.org/10.1023/A:1009472304903 (2000).
Miller, M. et al. A DNA array sensor utilizing magnetic microbeads and magnetoelectronic detection. J. Magn. Magn. Mater. 225, 138–144. https://doi.org/10.1016/S0304-8853(00)01242-7 (2001).
Jang, D.-Y. et al. Sublithographic vertical gold nanogap for label-free electrical detection of protein-ligand binding. J. Vac. Sci. Technol. B Microelectron. Nanometer. Struct. Process. Meas. Phenom. 25, 443–447. https://doi.org/10.1116/1.2713403 (2007).
Stern, E. et al. Label-free immunodetection with CMOS-compatible semiconducting nanowires. Nature 445, 519–522. https://doi.org/10.1038/nature05498 (2007).
Im, H., Huang, X.-J., Gu, B. & Choi, Y.-K. A dielectric-modulated field-effect transistor for biosensing. Nat. Nanotechnol. 2, 430–434. https://doi.org/10.1038/nnano.2007.180 (2007).
Gao, X. P., Zheng, G. & Lieber, C. M. Subthreshold regime has the optimal sensitivity for nanowire FET biosensors. Nano Lett. 10, 547–552. https://doi.org/10.1021/nl9034219 (2010).
Knoch, J., Mantl, S. & Appenzeller, J. Impact of the dimensionality on the performance of tunneling FETs: Bulk versus one-dimensional devices. Solid State Electron. 51, 572–578. https://doi.org/10.1016/j.sse.2007.02.001 (2007).
Anam, A., Amin, S. I., Prasad, D., Kumar, N. & Anand, S. Analysis of III–V material-based dual source T-channel junction-less TFET with metal implant for improved DC and RF performance. Micro Nanostruct. https://doi.org/10.1016/j.micrna.2023.207629 (2023).
Cherik, I. C., Abbasi, A., Maity, S. K. & Mohammadi, S. Junctionless tunnel field-effect transistor with a modified auxiliary gate, a novel candidate for high-frequency applications. Micro Nanostruct. https://doi.org/10.1016/j.micrna.2022.207477 (2022).
Oliva, N. et al. WSe 2/SnSe2 vdW heterojunction tunnel FET with subthermionic characteristic and MOSFET co-integrated on same WSe 2 flake.. NPJ 2D Mater. Appl. 4, 1–8. https://doi.org/10.1038/s41699-020-0142-2 (2020).
Cherik, I. C. & Mohammadi, S. Design insights into switching performance of germanium source L-shaped gate dopingless TFET based on cladding layer concept. IEEE Trans. Electron. Device. https://doi.org/10.1109/TED.2022.3229257 (2022).
Gopal, G., Garg, H., Agrawal, H. & Varma, T. Stacked ferroelectric heterojunction tunnel field effect transistor on a buried oxide substrate for enhanced electrical performance. Semicond. Sci. Technol. 37, 105006. https://doi.org/10.1088/1361-6641/ac830b (2022).
Saha, R., Goswami, R., Bhowmick, B. & Baishya, S. Simulation study of n+ pocket step shape heterodielectric double gate tunnel FET for switching and biosensing applications. Mater. Sci. Eng. B 293, 116491. https://doi.org/10.1016/j.mseb.2023.116491 (2023).
Singh, P. & Yadav, D. S. Impact of work function variation for enhanced electrostatic control with suppressed ambipolar behavior for dual gate L-TFET. Curr. Appl. Phys. 44, 90–101. https://doi.org/10.1016/j.cap.2022.09.014 (2022).
Anvarifard, M. K., Ramezani, Z. & Amiri, I. S. High ability of a reliable novel TFET-based device in detection of biomolecule specifies—A comprehensive analysis on sensing performance. IEEE Sens. J. 21, 6880–6887. https://doi.org/10.1109/JSEN.2020.3044056 (2020).
Verma, M., Tirkey, S., Yadav, S., Sharma, D. & Yadav, D. S. Performance assessment of a novel vertical dielectrically modulated TFET-based biosensor. IEEE Trans. Electron Device. 64, 3841–3848. https://doi.org/10.1109/TED.2017.2732820 (2017).
Cherik, I. C. & Mohammadi, S. Vertical tunneling field-effect transistor with germanium source and T-shaped silicon channel for switching and biosensing applications: A simulation study. IEEE Trans. Electron Device. 69, 5170–5176. https://doi.org/10.1109/TED.2022.3189326 (2022).
Priyadarshani, K. N. & Singh, S. Ultra sensitive label-free detection of biomolecules using vertically extended drain double gate Si0.5Ge0.5 source tunnel FET. IEEE Trans. Nanobiosci. 20, 480–487. https://doi.org/10.1109/TNB.2021.3106333 (2021).
Theja, A. & Panchore, M. Performance investigation of GaSb/Si heterojunction based gate underlap and overlap vertical TFET biosensor. IEEE Trans. Nanobiosci. https://doi.org/10.1109/TNB.2022.3183934 (2022).
Kumar, S., Singh, Y., Singh, B. & Tiwari, P. K. Simulation study of dielectric modulated dual channel trench gate TFET-based biosensor. IEEE Sens. J. 20, 12565–12573. https://doi.org/10.1109/JSEN.2020.3001300 (2020).
Gedam, A., Acharya, B. & Mishra, G. P. Design and performance assessment of dielectrically modulated nanotube TFET biosensor. IEEE Sens. J. 21, 16761–16769. https://doi.org/10.1109/JSEN.2021.3080922 (2021).
Gedam, A., Acharya, B. & Mishra, G. P. Design of a double cavity nanotube tunnel field-effect transistor-based biosenser. ECS J. Solid State Sci. Technol. 11, 081012. https://doi.org/10.1149/2162-8777/ac8835 (2022).
Shreya, S., Khan, A. H., Kumar, N., Amin, S. I. & Anand, S. Core-shell junctionless nanotube tunnel field effect transistor: Design and sensitivity analysis for biosensing application. IEEE Sens. J. 20, 672–679. https://doi.org/10.1109/JSEN.2019.2944885 (2019).
Cherik, I. C. & Mohammadi, S. Dielectric modulated doping-less tunnel field-effect transistor, a novel biosensor based on cladding layer concept. IEEE Sens. J. 22, 10308–10314. https://doi.org/10.1109/JSEN.2022.3163475 (2022).
Singh, S. & Singh, S. Dopingless negative capacitance ferroelectric TFET for breast cancer cells detection: Design and sensitivity analysis. IEEE Trans. Ultrason. Ferroelectr. Freq. Control 69, 1120–1129. https://doi.org/10.1109/TUFFC.2021.3136099 (2021).
Venkatesh, P., Nigam, K., Pandey, S., Sharma, D. & Kondekar, P. A dielectrically modulated electrically doped tunnel FET for application of label free biosensor. Superlattices Microstruct. 109, 470–479. https://doi.org/10.1016/j.spmi.2017.05.035 (2017).
Cherik, I. C. & Mohammadi, S. Impact of trap-related non-idealities on the performance of a novel TFET-based biosensor with dual doping-less tunneling junction. Sci. Rep. 13, 11495. https://doi.org/10.1038/s41598-023-38651-3 (2023).
Choudhury, S. et al. Modeling and simulation of a TFET-based label-free biosensor with enhanced sensitivity. Chemosensors 11, 312. https://doi.org/10.3390/chemosensors11050312 (2023).
Palepu, J. et al. Investigation of the dielectrically modulated electron hole bilayer tunnel field effect transistor for biomolecule detections. Curr. Appl. Phys. https://doi.org/10.1016/j.cap.2023.01.001 (2023).
Patil, M., Gedam, A. & Mishra, G. P. Performance assessment of a cavity on source chargeplasma TFET-based biosensor. IEEE Sens. J. 21, 2526–2532. https://doi.org/10.1109/JSEN.2020.3027031 (2020).
Silvaco. ATLAS Device Simulation Software User’s Manual, No. Version 3.2 (2015).
Kim, S. W., Kim, J. H., Liu, T.-J.K., Choi, W. Y. & Park, B.-G. Demonstration of L-shaped tunnel field-effect transistors. IEEE Trans. Electron. Devices 63, 1774–1778. https://doi.org/10.1109/TED.2015.2472496 (2015).
Yang, Z. Tunnel field-effect transistor with an L-shaped gate. IEEE Electron Device Lett. 37, 839–842. https://doi.org/10.1109/LED.2016.2574821 (2016).
Boucart, K. & Ionescu, A. M. A new definition of threshold voltage in tunnel FETs. Solid State Electron. 52, 1318–1323. https://doi.org/10.1016/j.sse.2008.04.003 (2008).
Dwivedi, P., Singh, R., Sengar, B. S., Kumar, A. & Garg, V. A new simulation approach of transient response to enhance the selectivity and sensitivity in tunneling field effect transistor-based biosensor. IEEE Sens. J. 21, 3201–3209. https://doi.org/10.1109/JSEN.2020.3028153 (2020).
Sarkar, A., Das, A. K., De, S. & Sarkar, C. K. Effect of gate engineering in double-gate MOSFETs for analog/RF applications. Microelectron. J. 43, 873–882. https://doi.org/10.1016/j.mejo.2012.06.002 (2012).
Sant, S., Schenk, A., Moselund, K. & Riel, H. In 2016 74th Annual Device Research Conference (DRC) 1–2. https://doi.org/10.1109/DRC.2016.7548413 (IEEE, 2016).
Wadhwa, G. & Raj, B. Design, simulation and performance analysis of JLTFET biosensor for high sensitivity. IEEE Trans. Nanotechnol. 18, 567–574. https://doi.org/10.1109/TNANO.2019.2918192 (2019).
Mukhopadhyay, S., Sen, D., Goswami, B. & Sarkar, S. K. Performance evaluation of dielectrically modulated extended gate single cavity InGaAs/Si HTFET based label-free biosensor considering non-ideal issues. IEEE Sens. J. 21, 4739–4746. https://doi.org/10.1109/JSEN.2020.3033576 (2020).
Dixit, A., Samajdar, D. P. & Bagga, N. Dielectric modulated GaAs1 − x Sb X FinFET as a label-free biosensor: Device proposal and investigation. Semicond. Sci. Technol. 36, 095033. https://doi.org/10.1088/1361-6641/ac0d97 (2021).
Dixit, A., Samajdar, D. P. & Chauhan, V. Sensitivity analysis of a novel negative capacitance FinFET for label-free biosensing. IEEE Trans. Electron Devices 68, 5204–5210 (2021).
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I.C.C.: Conceptualization, Methodology, Software, Formal analysis, Investigation, Visualization, Data Curation, Writing—Original Draft. S.M.: Conceptualization, Validation, Supervision, Project administration, Resources, Data Curation, Writing—Review & Editing.
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Chahardah Cherik, I., Mohammadi, S. Fringe-fields-modulated double-gate tunnel-FET biosensor. Sci Rep 14, 168 (2024). https://doi.org/10.1038/s41598-023-50723-y
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DOI: https://doi.org/10.1038/s41598-023-50723-y
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