Ultra-Low Specific On-resistance Lateral Double-Diffused Metal-Oxide-Semiconductor Transistor with Enhanced Dual-Gate and Partial P-buried Layer

Abstract

An ultra-low specific on-resistance (R_on,sp) lateral double-diffused metal-oxide-semiconductor transistor (LDMOS) with enhanced dual-gate and partial P-buried layer is proposed and investigated in this paper. On-resistance analytical model for the proposed LDMOS is built to provide an in-depth insight into the relationship between the drift region resistance and the channel region resistance. N-buried layer is introduced under P-well to provide a low-resistance conduction path and reduce the resistance of the channel region significantly. Enhanced dual-gate structure is formed by N-buried layer while avoiding the vertical punch-through breakdown in off-state. Partial P-buried layer with optimized length is adopted under the N-drift region to extend vertical depletion region and relax the electric field peak in off-state, which enhances breakdown voltage (BV) with low drift region resistance. For the LDMOS with enhanced dual-gate and partial P-buried layer, the result shows that R_on,sp is 8.5 mΩ·mm² while BV is 43 V.

Background

With the increase of demand for more complex and faster logic function in analog power IC, it is significant to improve the performance of the lateral double-diffused metal-oxide-semiconductor transistor (LDMOS), specially minimizing specific on-resistance (R_on,sp) and maximizing off-state breakdown voltage (BV) [1,2,3,4,5,6,7,8,9]. Most developed technologies focus on the drift region optimizing to improve the trade-off of R_on,sp vs. BV for LDMOS devices [10,11,12,13,14,15,16,17,18,19,20]. In our previous work, the LDMOS with ultra-shallow trench isolation (USTI) was proposed [21]. The depth and corner angel of USTI were optimized to achieve best-in-class performance. However, for the low voltage LDMOS, the drift region is losing domination in R_on,sp and the contribution of the channel region cannot be ignored.

Method

In this work, a novel ultra-low specific on-resistance LDMOS with enhanced dual-gate and partial P-buried layer is investigated. The physical models IMPACT.I, BGN, CONMOB, FLDMOB, SRH, and SRFMOB are used in numerical simulation. On-resistance analytical model is proposed to provide an in-depth insight into the relationship between the drift region resistance and the channel region resistance. Based on the model, N-buried layer and partial P-buried layer are optimized to achieve low R_on,sp and high BV.

Results and Discussion

Figure 1a shows the schematic cross-section of ultra-low specific on-resistance LDMOS with enhanced dual-gate and partial P-buried layer. The LDMOS features the dual-gate with N-buried layer and the partial P-buried layer which contributes to reduce R_on,sp and enhance BV, respectively. In the channel region, the enhanced dual-gate is formed by trench gate and highly doped N-buried layer. Compare to conventional dual-gate structure, N-buried layer significantly reduce the resistance of the channel region by provide a low on-resistance conduction path under P-well in the on-state. In the drift region, the partial P-buried layer with high doping concentration is introduced under the N-drift region to enhance BV while maintaining low R_on,sp. The partial P-buried layer helps to reduce the vertical electric field in the off-state without breaking charge balance in the drift region. The key size of the novel device is listed in Table 1.

Fig. 1

a Schematic cross-section view of ultra-low specific on-resistance LDMOS with enhanced dual-gate and partial P-buried layer. b Schematic equivalent on-resistance for the proposed LDMOS

Table 1 The key size of the novel device

Figure 1b shows the schematic equivalent on-resistance model for the proposed LDMOS. The total on-resistance is considered as the resistance of the drift region (R_d) and the resistance of the channel region (R_c) in series. In the channel region, surface channel conduction path parallels the trench channel conduction path. Thus, R_c is equal to (R_chs + R_acc)//(R_cht + R_nb), where R_chs, R_acc, R_cht, and R_nb are the resistances of the surface-gate channel, the accumulation region, the trench gate channel, and the N-buried layer, respectively. Based on the proposed on-resistance model, the reduction of R_c would achieve by decreasing R_nb without affecting the other performances, because the other resistances are mainly determinate by the process technology, operation voltage, and threshold voltage. The R_d has been reduced by introducing P-buried layer under N-drift region to enhance the Reduce Surface-field (RESURF) effect in our previous work. In this work, the partial P-buried layer is adopted to improve the BV while maintaining the low R_d.

Aiming at the reduction of R_c, the N-buried layer with high doping concentration is introduced under P-well. Figure 2 shows numerical and analytical R_c as functions of the doping concentration of the N-buried layer (N_nb) with single-gate and dual-gate. It is indicated that the dual-gate structure helps to reduce R_c compared with the single-gate. When N_nb = N_d = 5.5 × 10¹⁶ cm⁻³, R_c is 110 mΩ. According to the on-resistance model, R_nb is the main contributor to R_c. And then, the R_nb is desired to decrease with the aim of smaller R_c. As shown in Fig. 2a, R_c is reduced with N_nb increasing. When N_nb = 1.35 × 10¹⁷ cm⁻³, R_c is reduced to 85 mΩ. However, Fig. 2 also shows that N_nb would be limited by punch-through breakdown. Because of adding trench gate, R_c is decreased firstly by 34% with N_nb = N_d = 5.5 × 10¹⁶ cm⁻³. As N_nb increases, R_c continuously decreases. With optimized N_nb = 1.05 × 10¹⁷ cm⁻³, R_c is decreased by 45% at last. When N_nb > 1.05 × 10¹⁷ cm⁻³, punch-through breakdown will happen in P-well. The analytical result of R_on,sp shown in Fig. 2 indicates that the proposed model provides a good fitting with numerical simulation results. Therefore, the model is believable to guide the optimization design.

Fig. 2

Numerical and analytical R_c as a function of N_nb with single-gate and dual-gate (Z = 1 cm). N_d is the doping concentration of the N-drift region

Figure 3a shows numerical BV as a function of N_nb with different doping concentration of P-well (N_pwell). N_nb has an effect on not only the R_c, but also the BV. For a given N_pwell, BV keeps unchanged at small N_nb, and then decreases with N_nb increasing. When N_nb increases to 1.2 × 10¹⁷ cm⁻³, BV starts to drop with N_pwell = 2 × 10¹⁷ cm⁻³. The drop of BV is ascribed to punch-through breakdown in the P-well region as shown in Fig. 3b. As drain voltage increases, the depletion region in P-well extends to the source. When the depletion region attacks the N+/P-well junction, the punch-through breakdown occurs. For a large N_pwell, the depletion mainly extends to the drift region, and the punch-through breakdown is avoided without degrading the BV. Although P-well with high doping concentration benefits to avoid the punch-through breakdown, it would enhance the threshold voltage. Thus, N_pwell of 2 × 10¹⁷ cm⁻³ is chosen with consideration to threshold voltage and the trade-off between the BV and R_on,sp.

Fig. 3

a Numerical BV as a function of N_nb with different N_pwell. b Current density profile for N_nb = 10.5 × 10¹⁶ cm⁻³ and 14.5 × 10¹⁶ cm⁻³ while N_pwell = 2 × 10¹⁷ cm⁻³ at breakdown

In order to achieve low R_d and high BV, partial P-buried layer is introduced under the N-drift region. Figure 4a shows BV as a function of ΔL_pb with different N_pb. For a given N_pb, as ΔL_pb increases, BV increases and then decreases slightly. When ΔL_pb = 0.1 μm, N_pb = 1 × 10¹⁷ cm⁻³, BV reaches the maximum value 43 V. The insert shows the equipotential contour profile with N_pb = 1 × 10¹⁷ cm⁻³. It is indicated that the equipotential contour in the partial P-buried layer structure extends more to substrate with comparison to full P-buried layer. Figure 4b shows electric field distribution at the surface and the P-buried/N-drift junction interface. For optimized conventional LDMOS, the breakdown occurs usually at the N-drift/P-buried interface. For the proposed LDMOS, the junction of N-drift/P-sub replaces the junction of N-drift/P-buried to relax the vertical electric field and extend depletion region, which results in a higher BV while maintaining low R_d.

Fig. 4

a BV as a function of ΔL_pb with different N_pb. The insert is the equipotential contour profile with N_pb = 1 × 10¹⁷ cm⁻³. b Electric field distribution at the surface and the P-buried/N-drift junction interface

Charge balance between N-drift and partial P-buried layer is required to achieve high BV. Figure 5a shows that numerical and analytical BV and R_on,sp as functions of the doping concentration of the P-buried (N_pb) for different N_d. For a given N_d, BV has a maximum value with varied N_pb, and the maximum of BV increases with the decrease of N_d. However, R_on,sp can be increased as the N_d decreasing. Due to BV required higher than 40 V, the N_d = 5.5 × 10¹⁶ cm⁻³ and N_pb = 1 × 10¹⁷ cm⁻³ are chosen. Figure 5b shows numerical and analytical BV and R_on,sp as functions of the thickness of the STI layer (T_sti). T_sti has strong impact on BV and R_on,sp, and it should be designed and optimized carefully as well as our previous work [21]. For T_sti < 0.3 μm, the breakdown point under the edge of poly field plate has a high electric field peak. As T_sti increases, the electric field peak is relaxed, and then BV increases. For T_sti = 0.3 μm, BV of 43 V is obtained. For T_sti ≥ 0.3 μm, the electric field peak under the edge of poly field plate is enough low, as a result, the breakdown point transfers to P/N junction under the drain side. As T_sti increases, BV increases and then saturates.

Fig. 5

a Numerical (dotted line) and analytical (solid line) BV and R_on,sp as functions of N_pb for different N_d. b Numerical (dotted line) and analytical (solid line) BV and R_on,sp as functions of T_sti

Figure 6 shows the benchmark of existing Bipolar-CMOS-DMOS (BCD) technologies and the proposed LDMOS. Apparently, the process technology for proposed LDMOS is compatible with our developed BCD technology which achieved the best-in-class performance of LDMOS. In the fabrication process for the proposed LDMOS, N-buried layer could share the same mask with P-well. For the proposed LDMOS, R_on,sp is 8.5 mΩ·mm² while BV = 43 V, which is reduced by about 37% compared with our previous work.

Fig. 6

The benchmark of existing BCD technologies and the proposed LDMOS

Conclusion

A novel ultra-low specific on-resistance LDMOS with enhanced dual-gate and partial P-buried layer is proposed and investigated by numerical simulation in this paper. N-buried layer with high doping concentration is utilized to achieve enhanced dual-gate with reducing R_c. Partial P-buried layer is introduced under the N-drift region to enhance BV with keeping charge balance. The fabrication process of the LDMOS in this work is compatible with the existing BCD technology reported in our previous work. The result shows that the R_on,sp of the proposed LDMOS is reduced by 37% at BV of 43 V compared with previous work. With the semiconductor processing technology going to nanometer level, the R_on,sp can reduce further with channel length decrease.