CN100556795C - The preparation method of radio-frequency micro-machinery series contact type switch - Google Patents
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- CN100556795C CN100556795C CNB2007101760825A CN200710176082A CN100556795C CN 100556795 C CN100556795 C CN 100556795C CN B2007101760825 A CNB2007101760825 A CN B2007101760825A CN 200710176082 A CN200710176082 A CN 200710176082A CN 100556795 C CN100556795 C CN 100556795C
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Abstract
The present invention relates to the preparation method of radio-frequency micro-machinery series contact type switch, belong to semiconductor devices and production of integrated circuits technical field, this method comprises: with the silicon chip is substrate, and cleans; Sputter, plating, deposit, photoetching, etching form co-planar waveguide and bottom electrode; Spin coating is also solidified sacrifice layer, splash-proofing sputtering metal, deposit medium; The graphical bridge membrane switch that forms with serial aperture; The side direction undercutting; Releasing sacrificial layer.This method can be avoided the problem of stress concentration of medium bridge film, improves the Mechanical Reliability of switch, improves the yield rate and the service life of switch; Simultaneously, this method and CMOS process compatible are expected to be used widely.
Description
Technical field
The invention belongs to semiconductor devices and production of integrated circuits technical field, the particularly preparation method of radio-frequency micro-machinery series contact type switch is intended to improve the Mechanical Reliability of switch, the service life of improving switch.
Background technology
Since the last century the nineties, the integrated level of wireless telecommunication system improves constantly, and utilizes silicon technology to make monolithic radio frequency integrated circuit (RFIC), becomes present research focus.Integrated circuit extensively adopts CMOS technology, and traditional passive element mostly is discrete device, can't be integrated with IC.Most of and the CMOS process compatible of micromechanics (MEMS) technology can be realized passive device miniaturization and integrated purpose, and being expected provides new solution for silicon RFIC.Switch is an important class passive device, in radar system (5-94GHz), satellite communication system (12-35GHz), wireless communication system (0.8-6GHz) and measuring instrument system (0.01-50GHz) important use is arranged all.Therefore, make switch with micro mechanical technology and have important Research Significance.Micro-machinery switch is divided into number of different types, and wherein, the series contact type micro-machinery switch is because its superperformance in the broad band low frequency scope has broad application prospects.People often adopt two end supports bridge that static the drives functional part as switch, and with conducting metal or the dielectric material as the bridge film.Yet, adopt the metal bridge material, in order to isolate microwave signal and control signal, need extra high resistant offset line to connect with electrode, this has increased the complexity of manufacture craft.Adopt the medium bridge material, can isolate microwave signal and control signal naturally, but need to pay close attention to the Mechanical Reliability of medium bridge.
The mechanical failure of medium bridge mainly occurs in area of stress concentration, and area of stress concentration mainly is to produce in manufacturing process.The common methods of making medium bridge series contact type switch, particularly medium bridge and subsidiary electrode, contacting metal is as shown in Figure 1:
(1) is substrate with the silicon chip, and cleans; In the silicon chip front, form co-planar waveguide ground wire, the co-planar waveguide signal of band salient point and the bottom electrode of surface coverage insulating medium layer by surface micromechanical process such as sputter, plating, deposit, photoetching, etchings.
(2) after spin coating on the above-mentioned insulating medium layer and solidifying sacrifice layer 1, vacuum sputtering layer of metal 2 is shown in Fig. 1 (a).
(3) on metal level 2 with photoresist as mask, graphical this metal level, the contacting metal 21 in the middle of forming and the top electrode 22 of both sides are shown in Fig. 1 (b).
(4) dielectric layer deposited on above-mentioned graphical this metal level again, and be etched into the shape of bridge film, form switch medium bridge 3, shown in Fig. 1 (c).
(5) last dry method releasing sacrificial layer, the switch medium bridge structure that obtains suspending is shown in Fig. 1 (d).
Because what micro mechanical technology adopted is surface processing technique, upper layer film changes with the variation of following topology, and therefore, medium bridge can form fluctuating when the deposit of lower metal layer discontinuity zone place, and causes stress to concentrate.Mechanical breaking takes place at this place and lost efficacy in switch that making obtains easily.
Summary of the invention
The objective of the invention is to overcome the deficiency of prior art, propose a kind of preparation method of radio-frequency micro-machinery series contact type switch, be intended to avoid the formation of bridge membrane stress concentration zones, improve the Mechanical Reliability of switch, increase and make yield rate, improve the working life of switch.
The preparation method of radio-frequency micro-machinery series contact type switch of the present invention is characterized in that, may further comprise the steps:
(1) is substrate with the silicon chip, and cleans; In the silicon chip front, form co-planar waveguide ground wire, the co-planar waveguide signal of band salient point and the bottom electrode of surface coverage insulating medium layer by sputter, plating, deposit, photoetching, etching surface micromechanical process;
(2) on above-mentioned insulating medium layer behind spin coating and the cure polyimide sacrifice layer, the vacuum sputtering layer of metal;
(3) direct deposit one deck dielectric layer on metal level, patterned media layer and metal level form the switch bridge film with serial aperture then;
(4) spin coating photoresist and carry out photoetching on above-mentioned figure under the protection of photoresist, carries out side direction undercutting by aperture to metal level with carving metallic solution then, the contacting metal in the middle of forming and the top electrode of both sides;
(5) last dry method part releasing sacrificial layer, the switch medium bridge structure that obtains suspending.
The concrete steps in above-mentioned (1) step can be:
(11) be equipped with sheet, cleaning, oxidation: the high resistant silicon chip that with thickness is 400-600 μ m, single-sided polishing is as substrate, after the method that adopts sulfuric acid+hydrogen peroxide to boil is cleaned, with rinsed with deionized water and oven dry, again silicon chip is put into oxidation furnace, 1000-1100 ℃ of following and pure zirconia reaction, look unfamiliar into the thick oxide layer (SiO of 600-1000nm at silicon wafer polishing
2);
(12) photoetching for the first time, formation salient point: to the SiO that generates
2Layer carries out photoetching, exposes the zone that needs etching, carries out etching and control time with buffered hydrofluoric acid solution, forms high salient point shape about 200-400nm, and keeps remaining SiO
2As the barrier layer, remove photoresist then;
(13) sputter copper (Cu) seed layer: at SiO
2The Cu that sputter 200-400nm is thick above the layer is as seed layer;
(14) photoetching for the second time, plating Cu: above the Cu seed layer, form electroplating mold with the thick glue of photoetching, and in acid copper sulfate solution, electroplate, form the thick Cu layer pattern of about 1.5-3 μ m;
(15) sputter gold (Au) layer: the Au layer that sputter 200-400nm is thick on above-mentioned figure, as the contact material of switch.
(16) positive glue is peeled off: silicon chip is immersed in the acetone soln, under the ultrasonic water bath environment, Au layer on the glue is carried out positive glue peel off.
(17) go seed layer: under the protection of Au layer, carry out etching, remove remaining Cu seed layer, form waveguide and lower electrode arrangement with sulfuric acid+hydrogen peroxide.
(18) deposit silicon nitride (SiN) insulating barrier, photoetching for the third time: adopt to strengthen the thick SiN layer of plasma chemistry gas deposit (PECVD) technology deposit 200-400nm on above-mentioned figure, and carry out photoetching for the third time, with the graphical SiN of reactive ion etching (RIE) method, be formed on the insulating barrier of bottom electrode top, remove photoresist subsequently.
In above-mentioned (2) step, sacrifice layer can be the thick polyimides (PI) of 4-6 μ m, and metal level can be the thick Au layer of 200-400nm of vacuum sputtering.
In above-mentioned (3) step, dielectric layer can be the thick silicon oxynitride (SiON) of 500-700nm of pecvd process deposit.
In above-mentioned (4) step, the metallic solution at quarter of employing is iodine/liquor kalii iodide, and each composition proportion is: KI: iodine: water=5-15g: 1-4g: 50-150ml.
Characteristics of the present invention and beneficial effect:
Adopting above-mentioned technological process, mainly is the side direction undercutting technology in above-mentioned (4) step, can obtain smooth medium bridge film, avoids the formation of area of stress concentration, improves the switch Mechanical Reliability, increases and makes yield rate, improves the switch working life.Simultaneously,, can improve the integrated level of system greatly, reduce system cost and want, be expected to be used widely with a whole set of manufacturing process of CMOS process compatible.
Description of drawings
Fig. 1 is for making switch medium bridge and subsidiary electrode, the process chart of contacting metal common methods, wherein:
Fig. 1 (a) is the profile behind splash-proofing sputtering metal layer on the sacrifice layer;
Fig. 1 (b) is the profile behind graphical top electrode and the contacting metal;
Fig. 1 (c) for the deposit medium and finish the bridge film patternization after profile;
Fig. 1 (d) is the profile behind the releasing sacrificial layer.
Fig. 2 makes switch medium bridge and subsidiary electrode, the process chart of contacting metal side direction undercutting method for the present invention, wherein:
Fig. 2 (a) is the profile behind sputter Au layer on the PI sacrifice layer;
Fig. 2 (b) for deposit SiON and finish the bridge film patternization after profile;
Fig. 2 (c) is the profile in the side direction undercutting process;
Fig. 2 (d) is the profile behind the releasing sacrificial layer.
Fig. 3 makes the processing step embodiment flow chart of radio-frequency micro-machinery series contact type switch for the inventive method.
Fig. 3 (1) is the profile after the oxidation
Fig. 3 (2) is the profile behind the preparation salient point
Fig. 3 (3) is the profile after the sputter copper seed layer
Fig. 3 (4) is the profile after electroplating
Fig. 3 (5) is the profile behind the sputter gold
Fig. 3 (6) is the profile after positive glue is peeled off
Fig. 3 (7) is the profile after the removal residue seed layer
Fig. 3 (8) is for forming the profile behind the insulating barrier on the bottom electrode
Fig. 3 (9) for spin coating and solidify sacrifice layer after profile
Fig. 3 (10) is the profile behind sputter gold layer and the deposit silicon oxynitride layer
Fig. 3 (11) is that silicon oxynitride layer, gold layer are etched into the profile behind the bridge film with holes
Fig. 3 (12) is the profile of side direction undercutting method etching gold layer
Fig. 3 (13) is the profile behind the releasing sacrificial layer
The specific embodiment
The preparation method of a kind of radio-frequency micro-machinery series contact type switch of the present invention reaches embodiment in conjunction with the accompanying drawings and is described in detail as follows:
Method of the present invention as shown in Figure 2, may further comprise the steps:
(1) is substrate with the silicon chip, and cleans; In the silicon chip front, form co-planar waveguide ground wire, the co-planar waveguide signal of band salient point and the bottom electrode (not shown) of surface coverage insulating medium layer by surface micromechanical process such as sputter, plating, deposit, photoetching, etchings;
(2) on above-mentioned insulating medium layer spin coating and solidify sacrifice layer 1 after, vacuum sputtering layer of metal 2 is shown in Fig. 2 (a).
(3) direct deposit one deck dielectric layer 3 on metal level 2, patterned media layer 3 and metal level 2 form the switch bridge film with serial aperture 31, shown in Fig. 2 (b) then.
(4) spin coating photoresist 4 and carry out photoetching on above-mentioned figure under the protection of photoresist, carries out the side direction undercutting with carving metallic solution by 31 pairs of metal levels of aperture 2 then, and the contacting metal 21 in the middle of forming and the top electrode 22 of both sides are shown in Fig. 3 (c).
(5) last dry method releasing sacrificial layer, the switch medium bridge structure that obtains suspending is shown in Fig. 2 (d).
The concrete steps in above-mentioned (1) step can be:
(11) be equipped with sheet, cleaning, oxidation: the high resistant silicon chip that with thickness is 400-600 μ m, single-sided polishing is as substrate, after the method that adopts sulfuric acid+hydrogen peroxide to boil is cleaned, with rinsed with deionized water and oven dry, again silicon chip is put into oxidation furnace, 1000-1100 ℃ of following and pure zirconia reaction, look unfamiliar into the thick oxide layer (SiO of 600-1000nm at silicon wafer polishing
2);
(12) photoetching for the first time, formation salient point: to the SiO that generates
2Layer carries out photoetching, exposes the zone that needs etching, carries out etching and control time with buffered hydrofluoric acid solution, forms high salient point shape about 200-400nm, and keeps remaining SiO
2As the barrier layer, remove photoresist then;
(13) sputter copper (Cu) seed layer: at SiO
2The Cu that sputter 200-400nm is thick above the layer is as seed layer;
(14) photoetching for the second time, plating Cu: above the Cu seed layer, form electroplating mold with the thick glue of photoetching, and in acid copper sulfate solution, electroplate, form the thick Cu layer pattern of about 1.5-3 μ m;
(15) sputter gold (Au) layer: the Au layer that sputter 200-400nm is thick on above-mentioned figure, as the contact material of switch.
(16) positive glue is peeled off: silicon chip is immersed in the acetone soln, under the ultrasonic water bath environment, Au layer on the glue is carried out positive glue peel off.
(17) go seed layer: under the protection of Au layer, carry out etching, remove remaining Cu seed layer, form waveguide and lower electrode arrangement with sulfuric acid+hydrogen peroxide.
(18) deposit silicon nitride (SiN) insulating barrier, photoetching for the third time: adopt to strengthen the thick SiN layer of plasma chemistry gas deposit (PECVD) technology deposit 200-400nm on above-mentioned figure, and carry out photoetching for the third time, with the graphical SiN of reactive ion etching (RIE) method, be formed on the insulating barrier of bottom electrode top, remove photoresist subsequently.
In above-mentioned (3) step, dielectric layer can be the thick silicon oxynitride (SiON) of 500-700nm of pecvd process deposit.
In above-mentioned (4) step, the metallic solution at quarter of employing is iodine/liquor kalii iodide, and each composition proportion is: KI: iodine: water=5-15g: 1-4g: 50-150ml.
A kind of embodiment preparation flow of the inventive method may further comprise the steps as shown in Figure 3:
(1) be that N type high resistant (the 900 Ω cm) silicon chip 5 of 400 μ m single-sided polishings is as substrate with thickness, this silicon chip is put into sulfuric acid+hydrogen peroxide mixed solution (according to the concentrated sulfuric acid: the volume ratio configuration of hydrogen peroxide=4: 1) boiled 15 minutes, boil with deionized water then and dry; Silicon chip is put into oxidation furnace,, look unfamiliar into the thick SiO of 800nm at silicon wafer polishing 1050 ℃ of following and pure zirconia reactions
2Layer 6.Shown in Fig. 3 (1).
(2) coat negative photoresist in the silicon chip front that generates oxide layer, the reticle that dependence designs is exposed as mask and is developed, and exposes the part that needs etching; Wet etching in buffered hydrofluoric acid solution then is with expose portion SiO
2Layer is carved 300nm down; Etching is 40 minutes in the oxygen plasma atmosphere, removes photoresist, not the SiO that carves down
2Form the high salient point 61 of 300nm.Shown in Fig. 3 (2).
(3) at SiO
2Vacuum sputtering Cu300nm is as the seed layer 7 of electroplating above the layer.Shown in Fig. 3 (3).
(4) the thick positive photoresist AZ4620 of spin coating 6 μ m on seed layer, the reticle that dependence designs is exposed as mask and is developed, and forms electroplating mold 8; In acid copper sulfate solution, electroplated 9 minutes, form the thick Cu layer pattern 9 of 2 μ m.Shown in Fig. 3 (4).
(5) keep photoresist, the Au layer 10 that vacuum sputtering 300nm is thick on above-mentioned figure is as the contact material of switch.Shown in Fig. 3 (5).
(6) silicon chip is immersed in acetone and removes photoresist in the solution, and soaked 10 minutes in 50 ℃, the ultrasonic water bath environment of 150W, remove photoresist, the Au layer is peeled off with glue on the glue simultaneously; Etching 3 minutes in the oxygen plasma atmosphere then, remove may be residual photoresist.Shown in Fig. 3 (6).
(7) with the mask of Au layer as nature, silicon chip is immersed in sulfuric acid+hydrogen peroxide mixed solution, and (according to the concentrated sulfuric acid: 30% hydrogen peroxide: the volume ratio configuration of water=5: 1: 100) 2 minutes and 30 seconds, the remaining Cu seed layer of etching formed waveguide 91 and bottom electrode 92.Shown in Fig. 3 (7).
(8) on above-mentioned figure, with the thick SiN insulating barrier of PECVD method deposit 300nm; Spin coating positive photoresist, and the reticle that designs in the above exposes as mask and develops, and exposes SiN district to be etched, with the graphical SiN layer of RIE method, is formed on the insulating barrier 11 above the bottom electrode 92, removes photoresist subsequently.Shown in Fig. 3 (8).
(9) on above-mentioned figure, the thick PI in the spin coating 5 μ m left and right sides, and solidify to form sacrifice layer 1 with temperature-raising method, solidification process is 100 ℃, 130 ℃, 160 ℃, 190 ℃, 220 ℃ stepped intensifications, and, kept 30 minutes at 250 ℃ of constant temperature at last each temperature spot maintenance 5 minutes.Shown in Fig. 3 (9).
(10) on sacrifice layer, the Au layer 2 that vacuum sputtering 300nm is thick adopts the thick SiON layer 3 of PECVD method deposit 600nm as bridge film medium material immediately.Shown in Fig. 3 (10).
(11) spin coating positive photoresist on the SiON layer exposes as mask and develops with the reticle that designs, and exposes the zone that needs etching; With the graphical SiON layer of RIE method, form switch bridge film 3 with serial aperture 31; Then under the duplicate protection of photoresist and SiON bridge,, SiON bridge film 3 shapes with serial aperture 31 are transferred to the Au layer, form Au layer 2 with serial aperture with above-mentioned iodine/liquor kalii iodide wet etching Au layer; Remove photoresist subsequently.Shown in Fig. 3 (11).
(12) on above-mentioned figure, the positive glue photoresist 4 of spin coating exposes as mask and develops with the reticle that designs, and protection does not need the Au layer of etching; In above-mentioned iodine/liquor kalii iodide, carry out the side direction undercutting after about 6 minutes by the Au layer 2 under the 31 pairs of SiON bridges of aperture that expose, form the contacting metal 21 and the top electrode 22 that separate.Shown in Fig. 3 (12).
(13) remove photoresist, and etching discharged the PI sacrifice layer more than 120 minutes in the oxygen plasma atmosphere, the bridge film that obtains suspending is finished the making of switch.Shown in Fig. 3 (13).
Above-mentioned quarter, the embodiment of each composition proportion of iodine/liquor kalii iodide of Au was: KI: iodine: water=10g: 2.5g: 100ml.
Through statistics, adopt the yield rate of the switch of the inventive method preparation to reach 95%, average life span 4,000 ten thousand times.As a comparison, adopt non-side direction undercutting method, promptly common preparation method is made switch, and yield rate is less than 10%, and average life span is less than 1000 times.As seen, the present invention has improved the Mechanical Reliability of switch greatly, has improved the yield rate and the service life of switch.
Claims (4)
1, a kind of preparation method of radio-frequency micro-machinery series contact type switch is characterized in that, may further comprise the steps:
(1) is substrate with the silicon chip, and cleans; In the silicon chip front, form co-planar waveguide ground wire, the co-planar waveguide signal of band salient point and the bottom electrode of surface coverage insulating medium layer by sputter, plating, deposit, photoetching, etching surface micromechanical process;
(2) on above-mentioned insulating medium layer behind spin coating and the cure polyimide sacrifice layer, the vacuum sputtering layer of metal;
(3) direct deposit one deck dielectric layer on metal level, patterned media layer and metal level form the switch bridge film with serial aperture then;
(4) spin coating photoresist (4) and carry out photoetching on above-mentioned figure under the protection of photoresist, carries out side direction undercutting by aperture to metal level with carving metallic solution then, the contacting metal in the middle of forming and the top electrode of both sides;
(5) last dry method part releasing sacrificial layer, the switch medium bridge structure that obtains suspending.
2, the method for claim 1 is characterized in that, described (1) step specifically may further comprise the steps:
(11) be equipped with sheet, cleaning, oxidation: the high resistant silicon chip that with thickness is 400-600 μ m, single-sided polishing is as substrate, after the method that adopts sulfuric acid+hydrogen peroxide to boil is cleaned, with rinsed with deionized water and oven dry, again silicon chip is put into oxidation furnace, 1000-1100 ℃ of following and pure zirconia reaction, look unfamiliar into the thick SiO of 600-1000nm at silicon wafer polishing
2Oxide layer;
(12) photoetching for the first time, formation salient point: to the SiO that generates
2Layer carries out photoetching, exposes the zone that needs etching, carries out etching and control time with buffered hydrofluoric acid solution, forms high salient point shape about 200-400nm, and keeps remaining SiO
2As the barrier layer, remove photoresist then;
(13) sputter copper Cu seed layer: at SiO
2The Cu that sputter 200-400nm is thick above the layer is as seed layer;
(14) photoetching for the second time, plating Cu: above the Cu seed layer, form electroplating mold with the thick glue of photoetching, and in acid copper sulfate solution, electroplate, form the thick Cu layer pattern of about 1.5-3 μ m;
(15) sputter gold Au layer: the Au layer that sputter 200-400nm is thick on above-mentioned figure, as the contact material of switch;
(16) positive glue is peeled off: silicon chip is immersed in the acetone soln, under the ultrasonic water bath environment, Au layer on the glue is carried out positive glue peel off;
(17) go seed layer: under the protection of Au layer, carry out etching, remove remaining Cu seed layer, form waveguide and lower electrode arrangement with sulfuric acid+hydrogen peroxide;
(18) deposit silicon nitride SiN insulating barrier, photoetching for the third time: adopt to strengthen the thick SiN layer of plasma chemistry gas depositing technics deposit 200-400nm on above-mentioned figure, and carry out photoetching for the third time, with the graphical SiN of reactive ion etching method, be formed on the insulating barrier of bottom electrode top, remove photoresist subsequently;
3, method according to claim 1 is characterized in that in described (2) step, polyimide sacrificial layer thickness is 4-6 μ m, and metal level is the thick Au layer of the 200-400nm of vacuum sputtering.
4, method according to claim 1 is characterized in that in described (3) step, dielectric layer is the thick silicon oxynitride of the 500-700nm of pecvd process deposit (SiON).
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CN102107848B (en) * | 2009-12-25 | 2013-06-05 | 华东光电集成器件研究所 | Method of manufacturing suspension radio frequency switch |
CN102569054A (en) * | 2012-02-27 | 2012-07-11 | 中国科学院微电子研究所 | Preparation method of T-shaped grid |
US8629360B2 (en) * | 2012-04-30 | 2014-01-14 | Raytheon Company | RF micro-electro-mechanical system (MEMS) capacitive switch |
CN104576126A (en) * | 2015-01-22 | 2015-04-29 | 清华大学 | Carbon nano-tube MEMS switch and manufacturing method thereof |
CN106646175B (en) * | 2016-10-19 | 2019-06-25 | 东南大学 | Insertion type test chip and its preparation and application method based on the micro-nano mechanical manufacturing technology of silicon substrate |
CN108063363B (en) * | 2016-11-09 | 2019-12-27 | 中国科学院苏州纳米技术与纳米仿生研究所 | Integrated optoelectronic device and method of making the same |
CN112777563B (en) * | 2021-01-12 | 2023-09-26 | 清华大学 | Manufacturing method of airtight radio frequency MEMS device and airtight radio frequency MEMS device |
CN113086943B (en) * | 2021-03-31 | 2022-05-24 | 中国科学院半导体研究所 | Micro-nano radio frequency device and preparation method thereof |
CN113321179A (en) * | 2021-05-25 | 2021-08-31 | 曹建峰 | Method for manufacturing metal substrate for film sensor without polishing |
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