Polarization-enhanced sub-5 nm Janus MoSiGeN4 FET for high-performance and low-power applications

doi:10.1016/j.jmst.2025.07.066

Abstract

Abstract: Achieving ultra-short channel field-effect transistors (FETs) that cater to both high-performance (HP) and low-power (LP) applications simultaneously is an unremitting pursuit in the field. Herein, employing first-principles calculations, we investigate the performance of sub-5 nm FETs based on the Janus MoSiGeN₄ material and reveal the role of intrinsic out-of-plane electric polarization. We demonstrate that the synergistic effect of the intrinsic polarization field and the external electric field enhances the performance of Janus MoSiGeN₄ FETs over MoSi₂N₄ and MoGe₂N₄ FETs. Our simulations show that a 3 nm gate-length cold-source Janus MoSiGeN₄ FET, utilizing LaOCl as the dielectric material and an appropriate underlap structure, fulfills the HP and LP standards set by the International Technology Roadmap for Semiconductors (ITRS), with a subthreshold swing approaching the Boltzmann tyranny of 60 mV/dec. Notably, the optimized 1 nm gate-length MoSiGeN₄ FET achieves an on-state current of 990 µΑ/µm (HP) and 690 µΑ/µm (LP), surpassing other theoretical two-dimensional FETs at the same gate length. Taking the defect effects into account, the MoSiGeN₄ FET maintains a high on-state current that surpasses the ITRS for HP and LP standards. Our results provide a promising approach for designing ultra-short channel FETs suitable for both HP and LP applications.

Key words: Ultra-short channel transistors, Janus MoSiGeN₄, Electric dipole moment, Performance limit, Quantum transport calculations

Mi-Mi Dong, Chuan-Kui Wang, Xiao-Xiao Fu, Ming-Wen Zhao. Polarization-enhanced sub-5 nm Janus MoSiGeN₄ FET for high-performance and low-power applications[J]. J. Mater. Sci. Technol., 2026, 255: 47-55.

References

[1] R. Quhe, L. Xu, S. Liu, C. Yang, Y. Wang, H. Li, J. Yang, Q. Li, B. Shi, Y. Li, Y. Pan, X. Sun, J. Li, M. Weng, H. Zhang, Y. Guo, L. Xu, H. Tang, J. Dong, J. Yang, Z. Zhang, M. Lei, F. Pan, J. Lu, Phys. Rep. 938(2021) 1-72.
[2] L. Xu, J. Yang, C. Qiu, S. Liu, W. Zhou, Q. Li, B. Shi, J. Ma, C. Yang, J. Lu, Z. Zhang, ACS Appl. Mater. Interfaces 13 (2021) 31957-31967.
[3] M.E. Beck, M.C. Hersam, ACS Nano 14 (2020) 6498-6518.
[4] W. Zhao, D. Zou, Z. Sun, Y. Xu, G. Ji, X. Li, C. Yang, Adv. Electron. Mater. 8(2022) 2101359.
[5] H. Li, J. Liang, Q. Wang, F. Liu, G. Zhou, T. Qing, S. Zhang, J. Lu, Nano Res. 15(2021) 2522-2530.
[6] H. Zhang, B. Shi, L. Xu, J. Yan, W. Zhao, Z. Zhang, Z. Zhang, J. Lu, ACS Appl. Electron. Mater. 3(2021) 1560-1571.
[7] S.B. Desai, S.R. Madhvapathy, A.B. Sachid, J.P. Llinas, Q. Wang, G.H. Ahn, G. Pitner, M.J. Kim, J. Bokor, C. Hu, Science 354 (2016) 99-102.
[8] R. Quhe, Q. Li, Q. Zhang, Y. Wang, H. Zhang, J. Li, X. Zhang, D. Chen, K. Liu, Y. Ye, L. Dai, F. Pan, M. Lei, J. Lu, Phys. Rev. Appl. 10(2018) 024022.
[9] Y. Wang, R. Fei, R. Quhe, J. Li, H. Zhang, X. Zhang, B. Shi, L. Xiao, Z. Song, J. Yang, J. Shi, F. Pan, J. Lu, ACS Appl. Mater. Interfaces 10 (2018) 23344-23352.
[10] R. Quhe, J. Liu, J. Wu, J. Yang, Y. Wang, Q. Li, T. Li, Y. Guo, J. Yang, H. Peng, M. Lei, J. Lu, Nanoscale 11 (2019) 532-540.
[11] S. Liu, J. Yang, L. Xu, J. Li, C. Yang, Y. Li, B. Shi, Y. Pan, L. Xu, J. Ma, J. Yang, J. Lu, Nanoscale 13 (2021) 5536-5544.
[12] W. Zhou, S. Zhang, S. Guo, Y. Wang, J. Lu, X. Ming, Z. Li, H. Qu, H. Zeng, Phys. Rev. Appl. 13(2020) 044066.
[13] Y.L. Hong, Z. Liu, L. Wang, T. Zhou, W. Ma, C. Xu, S. Feng, L. Chen, M.L. Chen, D.M. Sun, X.Q. Chen, H.M. Cheng, W.C. Ren, Science 369 (2020) 670-674.
[14] Y. Li, C. Qi, X. Zhou, L. Xu, Q. Li, S. Liu, C. Yang, S. Liu, L. Xu, J. Dong, S. Fang, Z. Yang, Y. Chen, X. Sun, J. Lu, Phys. Rev. Appl. 20(2023) 064044.
[15] X. Sun, Z. Song, N. Huo, S. Liu, C. Yang, J. Yang, W. Wang, J. Lu, J. Mater. Chem. C 9 (2021) 14683-14698.
[16] H. Qu, S. Zhang, J. Cao, Z. Wu, Y. Chai, W. Li, L.J. Li, W. Ren, X. Wang, H. Zeng, Sci. Bull. 69(2024) 1427-1436.
[17] H. Qu, S. Zhang, H. Zeng, IEEE Electron Device Lett. 44(2023) 1492-1495.
[18] N.T.T.Binh, C.Q. Nguyen, T.V. Vu, C.V. Nguyen, J. Phys. Chem. Lett. 12(2021) 3934-3940.
[19] S.D. Guo, W.Q. Mu, Y.T. Zhu, R.Y. Han, W.C. Ren, J. Mater. Chem. C 9 (2021) 2464-2473.
[20] S.D. Guo, Y.T. Zhu, W.Q. Mu, X.Q. Chen, J. Mater. Chem. C 9 (2021) 7465-7473.
[21] S. Smidstrup, T. Markussen, P. Vancraeyveld, J. Wellendorff, J. Schneider, T. Gunst, B. Verstichel, D. Stradi, P.A. Khomyakov, U.G. Vej Hansen, M.E. Lee, S.T. Chill, F. Rasmussen, G. Penazzi, F. Corsetti, A. Ojanperä, K. Jensen, M.L.N. Palsgaard, U. Martinez, A. Blom, M. Brandbyge, K. Stokbro, J. Phys.: Condens. Matter 32 (2019) 015901.
[22] S.B. Desai, S.R. Madhvapathy, A.B. Sachid, J.P. Llinas, Q. Wang, G.H. Ahn, G. Pitner, M.J. Kim, J. Bokor, C. Hu, H.S.P. Wong, A. Javey, Science 354 (2016) 99-102.
[23] C. Qiu, Z. Zhang, M. Xiao, Y. Yang, D. Zhong, L.M. Peng, Science 355 (2017) 271-276.
[24] L. Wang, Y. Shi, M. Liu, A. Zhang, Y.L. Hong, R. Li, Q. Gao, M. Chen, W. Ren, H.M. Cheng, Y. Li, X.Q. Chen, Nat. Commun. 12(2021) 2361.
[25] S. Cahangirov, M. Topsakal, E. Aktürk, H. Şa hin, S.Ciraci, Phys. Rev. Lett. 102(2009) 236804.
[26] Y. Yu, J. Zhou, Z. Guo, Z. Sun, ACS Appl. Mater. Interfaces 13 (2021) 28090-28097.
[27] C. Zhang, F. Wei, X. Zhang, W. Chen, C. Chen, J. Hao, B. Jia, J. Solid State Chem. 315(2022) 123447.
[28] J.P. Colinge, Solid State Electron. 48(2004) 897-905.
[29] S. Das, J. Appenzeller, Appl. Phys. Lett. 103(2013) 103501.
[30] H. Fang, S. Chuang, T.C. Chang, K. Takei, T. Takahashi, A. Javey, Nano Lett. 12(2012) 3788-3792.
[31] P. Zhao, D. Kiriya, A. Azcatl, C. Zhang, M. Tosun, Y.S. Liu, M. Hettick, J.S. Kang, S. McDonnell, S. Kc, J. Guo, K. Cho, R.M. Wallace, A. Javey, ACS Nano 8 (2014) 10808-10814.
[32] S. Fathipour, P. Pandey, S.F. Shirey, A. Seabaugh, J. Appl. Phys. 120(2016) 234902.
[33] A. Pospischil, M.M. Furchi, T. Mueller, Nat. Nanotechnol. 9(2014) 257-261.
[34] R. Quhe, Z. Di, J. Zhang, Y. Sun, L. Zhang, Y. Guo, S. Wang, P. Zhou, Nat. Nanotechnol. 19(2024) 173-180.
[35] M.M. Dong, H. He, C.K. Wang, X.X. Fu, Nanoscale 15 (2023) 9106-9115.
[36] M.M. Dong, H. He, Y. Niu, C.K. Wang, X.X. Fu, ACS Appl. Nano Mater. 6(2023) 1541-1548.
[37] H. Li, Y. Liu, F. Liu, J. Lu, Phys. Rev. Appl. 20(2023) 034002.
[38] W. Cao, J. Kang, D. Sarkar, W. Liu, K. Banerjee, IEEE Trans. Electron Devices 62 (2015) 3459-3469.
[39] S. Liu, Q. Li, C. Yang, J. Yang, L. Xu, L. Xu, J. Ma, Y. Li, S. Fang, B. Wu, J. Dong, J. Yang, J. Lu, Phys. Rev. Appl. 18(2022) 054089.
[40] M.R. Osanloo, M.L.Van de Put, A.Saadat, W.G. Vandenberghe, Nat. Commun. 12(2021) 5051.
[41] Y.Y. Illarionov, A.G. Banshchikov, D.K. Polyushkin, S. Wachter, T. Knobloch, M. Thesberg, L. Mennel, M. Paur, M.S. Pollach, A.S. Thirsfeld, M.I. Vexler, M. Waltl, N.S. Sokolov, T. Mueller, T. Grasser, Nat. Electron. 2(2019) 230-235.
[42] S. Salahuddin, S. Datta, Nano Lett. 8(2008) 405-410.
[43] Z. Tang, C. Liu, X. Huang, S. Zeng, L. Liu, J. Li, Y.G. Jiang, D.W. Zhang, P. Zhou, Nano Lett. 21(2021) 1758-1764.
[44] J. Lyu, J. Pei, Y. Guo, J. Gong, H. Li, Adv. Mater. 32 (2019) 19060 0 0.
[45] H. Zhao, G. Yang, Y. Liu, X. Yang, Y. Gu, C. Wei, Z. Xie, Q. Zhang, B. Bian, X. Zhang, X. Huo, N. Lu, ACS Appl. Electron. Mater. 3(2021) 5086-5094.
[46] X. Liu, Y. Mao, ACS Appl. Electron. Mater. 5(2023) 6716-6724.
[47] Y. Guo, F. Pan, G. Zhao, Y. Ren, B. Yao, H. Li, J. Lu, Nanoscale 12 (2020) 15443-15452.
[48] Y. Pan, J. Dai, L. Xu, J. Yang, X. Zhang, J. Yan, J. Li, B. Shi, S. Liu, H. Hu, M. Wu, J. Lu, Phys. Rev. Appl. 14(2020) 024016.
[49] Q. Li, S. Fang, S. Liu, L. Xu, L. Xu, C. Yang, J. Yang, B. Shi, J. Ma, J. Yang, R. Quhe, J. Lu, ACS Appl. Mater. Interfaces 14 (2022) 23597-23609.
[50] A. Sengupta, A. Chanana, S. Mahapatra, AIP Adv. 5(2015) 027101.
[51] Q. Wang, L. Cao, S.J. Liang, W. Wu, G. Wang, C.H. Lee, W.L. Ong, H.Y. Yang, L.K. Ang, S.A. Yang, Y.S.Ang, npj 2D Mater.Appl. 5(2021) 71.
[52] C.C. Tho, S.D. Guo, S.J. Liang, W.L. Ong, C.S. Lau, L. Cao, G. Wang, Y.S. Ang, Appl. Phys. Rev. 10(2023) 041307.
[53] W. Ai, Y. Shi, X. Hu, J. Yang, L. Sun, ACS Appl. Electron. Mater. 5(2023) 5606-5613.
[54] Y. Li, L. Xu, C. Yang, L. Xu, S. Liu, Z. Yang, Q. Li, J. Dong, J. Yang, J. Lu, ACS Appl. Mater. Interfaces 16 (2024) 4 94 96-4 9507.
[55] X. He, W.Z. Li, Z. Gao, Z.H. Zhang, Y. He, J. Mater. Chem. C 11 (2023) 4728- 4741.
[56] X. Zhang, J.Y. Zheng, Y.C. Xiang, D. Wu, J. Fan, Y.Y. Sun, L.J. Chen, L.Y. Gan, X. Zhou, Appl. Phys. Lett. 123(2023) 023505.
[57] C.C. Tho, S. Fang, Y.S. Ang, APL Electron. Devices 1 (2025) 016111.
[58] W. Ai, X. Hu, T. Xu, J. Yang, L. Sun, Nanoscale Horiz. 10(2025) 635-646.
[59] J. Jiang, L. Xu, C. Qiu, L.M. Peng, Nature 616 (2023) 470-475.
[60] H.I. Un, J.Y. Wang, J. Pei, Adv. Sci. 6(2019) 1900375.
[61] L. Liu, Y. Lu, J. Guo, IEEE Trans. Electron Devices 60 (2013) 4133-4139.

Polarization-enhanced sub-5 nm Janus MoSiGeN₄ FET for high-performance and low-power applications

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 0

Recommended Articles

Metrics

Comments