[3] Yi X X, Shen H Z, Wang L C. Quantum entanglement, Bell inequality and their applications in quantum information processing[J]. Physics Experimentation, 42, 1-9(2022).

[4] Cheng L Y, Chen J Y, Meng Z. Generation of entangled coherent states in acoustic wave resonators coupled to a nitrogen-vacancy-center ensemble[J]. Journal of Quantum Optics, 27, 335-341(2021).

[5] Xiao C, Chen T H, Pan K Y et al. Generation of quadripartite entangled light field with continuous variable at different frequencies[J]. Acta Optica Sinica, 42, 231-237(2022).

[6] Zhang C L, Liu W W. Fast implementation of four-dimensional entangled state in separately coupled cavities via shortcut to adiabatic passage[J]. Acta Physica Sinica, 67, 160302(2018).

[7] Piccolini M, Giovannetti V, Franco R L. Robust engineering of maximally entangled states by identical particle interferometry[J]. Advanced Quantum Technologies, 6, 2300146(2023).

[8] Sawant R. A protocol to create a multi-particle entangled state for quantum-enhanced sensing[J]. Indian Journal of Physics, 97, 3781-3788(2023).

[9] Zhang L, Hao D H, Qiang W C. Preparation of three-atom W state in cavity QED[J]. Chinese Journal of Quantum Electronics, 37, 685-691(2020).

[10] Wu C, Hu Z N. Preparation and analysis of C-GHZ state based on weak cross-Kerr nonlinearity[J]. Chinese Journal of Quantum Electronics, 36, 584-590(2019).

[11] Zhang J, Yan F. A scheme for preparing special five-particle entangled state[J]. Chinese Journal of Quantum Electronics, 34, 462-466(2017).

[12] Kitagawa M, Ueda M. Squeezed spin states[J]. Physical Review A, 47, 5138(1993).

[13] Jin G R, Liu Y C, Liu W M. Spin squeezing in a generalized one-axis twisting model[J]. New Journal of Physics, 11, 073049(2009).

[14] Ma J, Wang X G, Sun C P et al. Quantum spin squeezing[J]. Physics Reports, 509, 89-165(2011).

[15] Sinatra A. Spin-squeezed states for metrology[J]. Applied Physics Letters, 120, 120501(2022).

[16] Qin W, Chen Y H, Wang X et al. Strong spin squeezing induced by weak squeezing of light inside a cavity[J]. Nanophotonics, 9, 4853-4868(2020).

[17] Huang L G, Chen F, Li X W et al. Dynamic synthesis of Heisenberg-limited spin squeezing[J]. npj Quantum Information, 7, 168(2021).

[18] Bai S Y, An J H. Generating stable spin squeezing by squeezed-reservoir engineering[J]. Physical Review Letters, 127, 083602(2021).

[19] Malinowski M, Zhang C, Negnevitsky V et al. Generation of a maximally entangled state using collective optical pumping[J]. Physical Review Letters, 128, 080503(2022).

[20] Kopylov W, Brandes T. Time delayed control of excited state quantum phase transitions in the Lipkin-Meshkov-Glick model[J]. New Journal of Physics, 17, 103031(2015).

[21] Opatrný T, Richterek L, Opatrný M. Analogies of the classical Euler top with a rotor to spin squeezing and quantum phase transitions in a generalized Lipkin-Meshkov-Glick model[J]. Scientific Reports, 8, 1984(2018).

[22] Gutiérrez-Ruiz D, Gonzalez D, Chávez-Carlos J et al. Quantum geometric tensor and quantum phase transitions in the Lipkin-Meshkov-Glick model[J]. Physical Review B, 103, 174104(2021).

[23] Law C K, Ng H T, Leung P T. Coherent control of spin squeezing[J]. Physical Review A, 63, 055601(2001).

[24] Pezzé L, Smerzi A. Entanglement, nonlinear dynamics, and the Heisenberg limit[J]. Physical Review Letters, 102, 100401(2009).