空腔型薄膜体声波滤波器的关键技术进展

doi:10.15541/jim20240355

无机材料学报 ›› 2025, Vol. 40 ›› Issue (2): 128-144.DOI: 10.15541/jim20240355 CSTR: 32189.14.10.15541/jim20240355

空腔型薄膜体声波滤波器的关键技术进展

陶桂龙¹^,²(), 支国伟², 罗添友², 欧阳佩东², 衣新燕³, 李国强¹^,²^,³()

1.华南理工大学集成电路学院, 广州 511442
2.华南理工大学发光材料与器件国家重点实验室, 广州 510640
3.广州市艾佛光通科技有限公司, 广州 510700

收稿日期:2024-07-27 修回日期:2024-09-12 出版日期:2025-02-20 网络出版日期:2024-11-25
通讯作者: 李国强, 教授. E-mail: msgli@scut.edu.cn
作者简介:陶桂龙(1988-), 男, 博士研究生. E-mail: ictgl@mail.scut.edu.cn
基金资助:
国家重点研发计划(2022YFB3604500);国家重点研发计划(2022YFB3604501)

Progress on Key Technologies of Cavity-structured Thin Film Bulk Acoustic Wave Filter

TAO Guilong¹^,²(), ZHI Guowei², LUO Tianyou², OUYANG Peidong², YI Xinyan³, LI Guoqiang¹^,²^,³()

1. School of Integrated Circuits, South China University of Technology, Guangzhou 511442, China
2. State Key Laboratory of Luminescent Materials and Devices, South China University of Technology, Guangzhou 510640, China
3. Guangzhou FLCT Communication Technology Co., Ltd., Guangzhou 510700, China

Received:2024-07-27 Revised:2024-09-12 Published:2025-02-20 Online:2024-11-25
Contact: LI Guoqiang, professor. E-mail: msgli@scut.edu.cn
About author:TAO Guilong (1988-), male, PhD candidate. E-mail: ictgl@mail.scut.edu.cn
Supported by:
National Key Research and Development Program of China(2022YFB3604500);National Key Research and Development Program of China(2022YFB3604501)

摘要/Abstract

摘要：

随着通信技术升级以及5G通信应用的驱动, 各种智能设备所需的滤波器数量激增, 促进了滤波器市场的繁荣, 但对其性能要求也越来越高, 例如大带宽、高频率、高功率容量、微型化、集成化以及低成本等指标是学术界与产业界重点关注的方向, 而基于薄膜体声波谐振器(Thin Film Bulk Acoustic Resonator, FBAR)技术的FBAR滤波器已成为最有前景的滤波器之一。另外, 当前空腔型FBAR滤波器已取得了一定的商业成功, 但是仍面临性能不足、工艺复杂、成本略高、技术受限等困境。为此, 本文试图从器件理论研究与结构优化、高性能压电材料制备与优化、新型工艺开发及技术融合三方面对FBAR滤波器的相关问题与关键技术进行综述, 旨在为该研究领域的学者梳理FBAR滤波器技术进阶与迭代的脉络, 以期为未来研究的路径与方向提供若干启发性思考。

关键词: FBAR滤波器, 理论研究, AlN压电薄膜, 技术融合, 综述

Abstract:

With upgrading of communication technology and driving of 5G communication applications, the explosive number of filters required by various smart devices promoted prosperity of the filter market. However, the demanded performance also becomes increasingly stringent, including broad bandwidth, high frequency, high power capacity, miniaturization, integration, and low cost, in both academia and industry. To meet these strict requirements, the thin film bulk acoustic resonator (FBAR) filters have emerged as one of the most promising types of filters with commercial success. But currently they are still facing difficulties such as insufficient performance, complex fabrication process, relatively higher cost, and technological constraints. This paper reviews the relevant issues and key technologies in FBAR filters in three aspects: theoretical research on devices and structural optimization, preparation and optimization of high-performance piezoelectric materials, and development of novel processes and technological integration. The purpose of this paper is to delineate the trajectory of technological advancements and iterations in FBAR filters for scholars in the research field, with the expectation of providing several considerations for future research directions and pathways.

Key words: FBAR filter, theoretical research, AlN piezoelectric film, technology integration, review

中图分类号:

TN713

陶桂龙, 支国伟, 罗添友, 欧阳佩东, 衣新燕, 李国强. 空腔型薄膜体声波滤波器的关键技术进展[J]. 无机材料学报, 2025, 40(2): 128-144.

TAO Guilong, ZHI Guowei, LUO Tianyou, OUYANG Peidong, YI Xinyan, LI Guoqiang. Progress on Key Technologies of Cavity-structured Thin Film Bulk Acoustic Wave Filter[J]. Journal of Inorganic Materials, 2025, 40(2): 128-144.

图/表 19

表1 SAW滤波器和BAW滤波器的技术特点

Table 1 Technical characteristics of SAW filter and BAW filter

Filter type	SAW filter	BAW filter
Characteristic	High stability, low insertion loss (2-4 dB)	High stability, low insertion loss (0.8-1.5 dB), high power tolerance
Applicable frequency range	10 MHz-3 GHz	1.5-6 GHz, the maximum up to over 10 GHz
Advantage	Smaller than the traditional ceramic filter, flexible, mature technology, high reliability	Suitable for high frequency, insensitive to temperature changes, miniaturized vertical propagation in acoustic wave, decreased size according to frequency increase
Limitation	Poor thermal stability, decreased Q-value when operating frequency exceeds 1.5 GHz	High manufacturing cost, complex manufacturing process

图1 基于L型结构的FBAR滤波器的工作原理

Fig. 1 Operating principle of the L-type FBAR filter (a) Electrical characteristics of the idealized FBAR; (b) Fundamental unit of the L-type structure; (c) Transmission response

图2 FBAR与压电薄膜的等效电路模型

Fig. 2 FBAR and the equivalent circuit model of piezoelectric thin film (a) Schematic structure of FBAR; (b) Mason equivalent circuit model of the piezoelectric thin film

图3 双工器的非线性失真[23]

Fig. 3 Nonlinear distortion of the duplexer[23] (a) Circuit diagram; (b) Signal distribution

图4 基于AlN薄膜的BAW谐振器[25]

Fig. 4 BAW resonator based on AlN thin film[25] (a) Nonlinear circuit model; (b) Second harmonic response; (c) Third harmonic response

图5 具有边缘布拉格反射层结构的谐振器[31]

Fig. 5 Resonator with edge Bragg reflection layer structure[31]

图6 FBAR的(a)横截面和(b)俯视图[35]

Fig. 6 (a) Cross-section and (b) top view of FBAR[35]

图7 BAW谐振器离散化模型及电极馈电引线[36]

Fig. 7 Discretized model and electrode feed lines of BAW resonator[36] (a) Schematic representation of discretized resonator model; (b) Two resonators in series and connected by broad lead; (c) Single resonator connected by narrow lead

图8 基于单晶和多晶AlN的3.55 GHz FBAR滤波器[54]

Fig. 8 3.55 GHz FBAR filter based on single-crystal and polycrystalline AlN[54] (a) Measured power sweep at right band edge of the filters; (b) Measured insertion loss of the filters versus input power

图9 单晶AlN-FBAR滤波器[55]

Fig. 9 Single crystal AlN-FBAR filter[55] (a) Actual layout; (b) Simulated and measured transmission response curves

图10 FBAR滤波器传输响应的测量值[64]

Fig. 10 Measured values of transmission response of FBAR filter[64]

图11 基于Al0.8Sc0.2N薄膜制备的FBAR滤波器的实验结果[65]

Fig. 11 Experimental results of FBAR filter fabricated with Al0.8Sc0.2N film[65] (a) Transmission response of FBAR filter; (b) Return loss of the FBAR filter

图12 Sc掺杂量对Al1−xScxN薄膜质量及表面形貌的影响[69]

Fig. 12 Effect of Sc-dopant concentration on crystal quality and surface morphology of Al1−xScxN thin films[69] (a-c) TEM dark-field images and electron diffraction patterns for 10%, 31%, and 42% Sc content; (d-f) Corresponding SEM plane views

图13 两步法(Sample 1)和单步PVD工艺(Sample 2)所获FBAR的性能对比[86]

Fig. 13 Performance comparison of FBAR obtained by two-step (Sample 1) and single PVD (Sample 2) processes[86] (a) Frequency impedance characteristic curves; (b) Smith chart

图14 SABAR工艺示意图[87]

Fig. 14 Schematic diagram for SABAR process[87] (a) Combination of PLD and MOCVD AlN film; (b) Bottom electrode and bonding layer sputtered on top of AlN layer; (c) Resonator structure

图15 结合FBAR与IPD技术的N77频段混合滤波器[88]

Fig. 15 N77-band hybrid filter based on FBAR and IPD technology[88] (a) Design schematic; (b) Simulated transmission response curve

图16 基于FBAR与IPD技术的N41频段混合滤波器[89]

Fig. 16 N41-band hybrid filter based on FBAR and IPD technology[89]

图17 用于滤波器参数预测的卷积混合网络[94]

Fig. 17 Convolutional hybrid network for the filter parameter prediction[94]

图18 LTE 4G/5G射频前端模块结构[98]

Fig. 18 LTE 4G/5G radio frequency front end module structure[98]

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空腔型薄膜体声波滤波器的关键技术进展

Progress on Key Technologies of Cavity-structured Thin Film Bulk Acoustic Wave Filter

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