CN202305565U - Tunnel scanning microscope with large range and high depth-to-width ratio measurement capacity - Google Patents
Tunnel scanning microscope with large range and high depth-to-width ratio measurement capacity Download PDFInfo
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- CN202305565U CN202305565U CN2011204243555U CN201120424355U CN202305565U CN 202305565 U CN202305565 U CN 202305565U CN 2011204243555 U CN2011204243555 U CN 2011204243555U CN 201120424355 U CN201120424355 U CN 201120424355U CN 202305565 U CN202305565 U CN 202305565U
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Abstract
The utility model discloses a tunnel scanning microscope with a large range and a high depth-to-width ratio measurement capacity. An L-shaped pedestal baseplate, a first switching board, an X-axis manual translation platform, a Y-axis manual translation platform, an X-axis direct current electric translation platform, a Y-axis direct current electric translation platform, a manual inclination table, a second switching board and a sample table are connected with one another sequentially, wherein a third switching board is arranged on the upper part of an L-shaped base side plate; a movable translation platform, a Z-axis direct current electric translation platform and a piezoelectric ceramic fixing block are arranged on the third switching board sequentially; the piezoelectric ceramic fixing block is vertically provided with piezoelectric ceramic; and a front-mounted amplification circuit unit, a probe clamping mechanism and a probe are arranged at the lower end of the piezoelectric ceramic sequentially. According to the tunnel scanning microscope, the measuring range of a tunnel scanning microscope technology is increased from the micrometer magnitude to the millimeter magnitude, and the depth-to-width measurement capacity is improved from 1: 1 to 50: 1; and therefore, the application capacity of the tunnel scanning microscope technology in the field of micro-nano measurement is improved.
Description
Technical field
The utility model relates to the PSTM technical field, particularly relates to a kind ofly having simultaneously on a large scale and profundity-wide PSTM than measurement capability.
Background technology
Have specific function small surface topology on a large scale, advanced-wide than three-dimensional micro-nano structure, comprising: (1) micro optical element, like groove, microlens array, little pyramid structure etc.; (2) minisize mould; Like two dimensional surface grating metal form, micro lens array molding die; LCD display light-conducting board mold etc.; They have become the key components and parts in fields such as photoelectricity, communication and precision measurement; Product that derives thus such as digital camera, facsimile recorder, scanner, high-resolution display system, optical-fibre communications, plane grating positioning system etc. have formed hundreds of millions of world markets, are playing the part of important role in many fields such as Aeronautics and Astronautics, electronics, chemical industry, biology, medical treatment, and wide application prospect is arranged.The shape of these three-dimensional micro-nano structures will directly influence the multinomial performance index of related device; As: driving force, operating frequency range, sensitivity and displacement etc.; Therefore very necessary to its ultra precise measurement of carrying out surface topography; And measure and to be used for guaranteeing to process, its precision often will be higher than processing one one magnitude at least.So, if do not have advanced measurement means and instrument to remove to guarantee or check the three-dimensional micro-nano structure that processes, the no standard of its processing can be followed, therefore so-called processing blindness just.Along with the continuous progress of modern micro-nano process technology, microcircuit, micro optical element, micromechanics and other various micro elements constantly occur, and are urgent all the more to large tracts of land, profundity-wide demand than the ultra precise measurement of micro-nano structure surface pattern.
In numerous ultra precise measurement technology, PSTM be still be the three-D micro-nano topography measurement the most directly, can reflect the effective tool of test specimen micro-nano structure strictly according to the facts.It has mainly utilized tunnel current that the quantum tunneling effect of needle point and sample room nano gap causes and has been partitioned into exponential relationship, realizes that the local of sample is surveyed.Though traditional PSTM measuring accuracy is very high, its longitudinal frame can reach 0.001-0.01nm, and lateral resolution is 1nm greatly also, yet the two cross measure length is generally several microns or tens micron dimensions.Traditional PSTM all is the scan pattern that adopts three-dimensional piezoelectric ceramic tube to drive; Can't implement at a high speed, on a large scale, the micro-nano measurement of profundity-wide ratio; Also make their usable range only limit to micro-nano pattern and geometric measurement in the laboratory; Do not possess on a large scale, the measurement capability of profundity-wide ratio, can't satisfy the growth requirement in present ultra precise measurement field.Therefore, at this on the one hand, be badly in need of original surveying instrument is improved, develop a kind of novel scanning tunneling microscopic detection system, it is had on a large scale simultaneously and the measurement capability of profundity-wide ratio.
Summary of the invention
The purpose of the utility model is the deficiency that overcomes prior art, provides a kind of and has simultaneously on a large scale and profundity-wide PSTM than measurement capability.
Have on a large scale and profundity-wide PSTM than measurement capability comprises L type pedestal, first card extender, X axle manual translation platform, Y axle manual translation platform, X axle direct current drive translation stage, Y axle direct current drive translation stage, manually inclination angle platform, second card extender, sample stage, the 3rd card extender, Z axle manual translation platform, Z axle direct current drive translation stage, piezoelectric ceramics fixed block, piezoelectric ceramics, pre-amplification circuit unit, probe clamping device and probe; L type pedestal bottom plate, first card extender, X axle manual translation platform, Y axle manual translation platform, X axle direct current drive translation stage, Y axle direct current drive translation stage, manual inclination angle platform, second card extender, sample stage link to each other in order; L type base side boards top is provided with the 3rd card extender; Be provided with Z axle manual translation platform, Z axle direct current drive translation stage, piezoelectric ceramics fixed block on the 3rd card extender in order; The piezoelectric ceramics fixed block vertically is provided with piezoelectric ceramics, and the piezoelectric ceramics lower end is provided with pre-amplification circuit unit, probe clamping device and probe in order.
The material of described the 3rd card extender is a nylon, and the material of probe is 99.999% pure tungsten.Be provided with counterbore in the middle of the described sample stage, circular magnet is housed in the counterbore.Described manual inclination angle platform is to have the manual inclination angle platform that two-dimentional angular motion degree of freedom is regulated.Described X axle direct current drive translation stage, Y axle direct current drive translation stage, Z axle direct current drive translation stage stroke are 30 mm.Described piezoelectric ceramics stroke is 150 μ m.
The utility model patent is compared main advantage with traditional PSTM and is: flat scanning mechanism by two dimension on a large scale the direct current generator drives platform form; Servo longitudinal mechanism is made up of long stroke piezoelectric ceramics, has overcome that the measuring speed that traditional PSTM adopts single 3 D piezoelectric scanning pipe to be brought is low, measurement range is little, dark-wide than technological deficiency such as a little less than the measurement capability.And, flat scanning mechanism and servo longitudinal mechanism are separated, avoided the coupling error between the motion of flat scanning and servo longitudinal, in the measurement range that improves PSTM, also improved its measuring accuracy.Utilize this novel PSTM; Can the measurement range of PSTM technology be risen to the mm magnitude from μ m magnitude; The depth-to-width ratio measurement capability has promoted the application power of technique of scan tunnel microscope in the micro-nano field of measurement greatly from rising to more than the 50:1 less than 1:1.
Description of drawings
Fig. 1 has on a large scale and profundity-wide PSTM structural representation than measurement capability,
Fig. 2 is the sample stage structural representation of the utility model;
Fig. 3 is a large area scanning plane inclination bearing calibration synoptic diagram;
Fig. 4 be utilize this novel PSTM offset of sinusoidal grating sample on a large scale and advanced-wide than scanning survey result;
Among the figure, L type marble pedestal 1, first card extender 2, X axle manual translation platform 3, Y axle manual translation platform 4, X axle direct current drive translation stage 5, Y axle direct current drive translation stage 6, manually inclination angle platform 7, second card extender 8, sample stage 9, testing sample 10, the 3rd card extender 11, Z axle manual translation platform 12, Z axle direct current drive translation stage 13, piezoelectric ceramics fixed block 14, piezoelectric ceramics 15, pre-amplification circuit unit 16, probe clamping device 17, probe 18.
Embodiment
Below in conjunction with accompanying drawing, this patent is further explained.
Shown in accompanying drawing 1, have on a large scale and profundity-wide PSTM than measurement capability comprises L type pedestal 1, first card extender 2, X axle manual translation platform 3, Y axle manual translation platform 4, X axle direct current drive translation stage 5, Y axle direct current drive translation stage 6, manually inclination angle platform 7, second card extender 8, sample stage 9, the 3rd card extender 11, Z axle manual translation platform 12, Z axle direct current drive translation stage 13, piezoelectric ceramics fixed block 14, piezoelectric ceramics 15, pre-amplification circuit unit 16, probe clamping device 17 and probe 18; L type pedestal 1 base plate, first card extender 2, X axle manual translation platform 3, Y axle manual translation platform 4, X axle direct current drive translation stage 5, Y axle direct current drive translation stage 6, manually inclination angle platform 7, second card extender 8, sample stage 9 link to each other in order; L type pedestal 1 side plate top is provided with the 3rd card extender 11; Be provided with moving translation stage 12, Z axle direct current drive translation stage 13, piezoelectric ceramics fixed block 14 on the 3rd card extender 11 in order; Piezoelectric ceramics fixed block 14 vertically is provided with piezoelectric ceramics 15, and piezoelectric ceramics 15 lower ends are provided with pre-amplification circuit unit 16, probe clamping device 17 and probe 18 in order.
The material of described the 3rd card extender 11 is a nylon, and the material of probe 18 is 99.999% pure tungsten.As shown in Figure 2, be provided with counterbore in the middle of the described sample stage 9, circular magnet is housed in the counterbore.Described manual inclination angle platform 7 is for having the manual inclination angle platform that two-dimentional angular motion degree of freedom is regulated.Described X axle direct current drive translation stage 5, Y axle direct current drive translation stage 6, Z axle direct current drive translation stage 13 strokes are 30 mm.Described piezoelectric ceramics 15 strokes are 150 μ m.
In actual the enforcement, to testing sample-measure big plane, the profundity-three-dimensional sinusoidal grating of wide ratio surface is carried out scanning tunneling microscopic and measured.In order to realize to three-dimensional sinusoidal grating on a large scale, advanced-wide than scanning; Need carry out plane inclination proofreaies and correct; To guarantee within whole large area scanning scope; Scan-probe and testing sample can both interact in the tunnel current zone, and promptly whole sweep limit is all within the servo travel range of piezoelectric ceramics.As shown in Figure 3, the step that plane inclination is proofreaied and correct is: 1. X axle direct current drive translation stage moves 1.2 mm
,The elongation that detects piezoelectric ceramics is 5 μ m, and the deflection angle of then regulating manual inclination angle platform is arctan (0.005/1.2); 2. Y axle direct current drive translation stage moves 1.2 mm
,Detect the stroke 4.5 μ m of piezoelectric ceramics, the luffing angle of regulating manual inclination angle platform is arctan (0.0045/1.2).Carry out after plane inclination proofreaies and correct, with this novel PSTM of utilization can be on a large scale, the measuring samples sinusoidal grating of profundity-wide ratio carries out on a large scale, the ultra precise measurement of profundity-wide specific surface pattern, the scanning survey result is as shown in Figure 4.Can find out from scanning result, utilize this patent of invention, can accurately obtain on a large scale, advanced-metrical information of wide surface topography than micro-nano structure.
Claims (6)
1. one kind has on a large scale and profundity-wide PSTM than measurement capability, it is characterized in that comprising L type pedestal (1), first card extender (2), X axle manual translation platform (3), Y axle manual translation platform (4), X axle direct current drive translation stage (5), Y axle direct current drive translation stage (6), manual inclination angle platform (7), second card extender (8), sample stage (9), the 3rd card extender (11), Z axle manual translation platform (12), Z axle direct current drive translation stage (13), piezoelectric ceramics fixed block (14), piezoelectric ceramics (15), pre-amplification circuit unit (16), probe clamping device (17) and probe (18); L type pedestal (1) base plate, first card extender (2), X axle manual translation platform (3), Y axle manual translation platform (4), X axle direct current drive translation stage (5), Y axle direct current drive translation stage (6), manual inclination angle platform (7), second card extender (8), sample stage (9) link to each other in order; L type pedestal (1) side plate top is provided with the 3rd card extender (11); Be provided with Z axle manual translation platform (12), Z axle direct current drive translation stage (13), piezoelectric ceramics fixed block (14) on the 3rd card extender (11) in order; Piezoelectric ceramics fixed block (14) vertically is provided with piezoelectric ceramics (15), and piezoelectric ceramics (15) lower end is provided with pre-amplification circuit unit (16), probe clamping device (17) and probe (18) in order.
2. according to claim 1 a kind ofly have on a large scale and profundity-wide PSTM than measurement capability, and the material that it is characterized in that described the 3rd card extender (11) is a nylon, and the material of probe (18) is 99.999% pure tungsten.
3. according to claim 1 a kind ofly have on a large scale and profundity-wide PSTM than measurement capability, it is characterized in that being provided with counterbore in the middle of the described sample stage (9), and circular magnet is housed in the counterbore.
4. according to claim 1 a kind ofly have on a large scale and profundity-wide PSTM than measurement capability, it is characterized in that described manual inclination angle platform (7) is for having the manual inclination angle platform that two-dimentional angular motion degree of freedom is regulated.
5. according to claim 1 a kind ofly have on a large scale and profundity-wide PSTM than measurement capability, it is characterized in that described X axle direct current drive translation stage (5), Y axle direct current drive translation stage (6), Z axle direct current drive translation stage (13) stroke are 30 mm.
6. according to claim 1 a kind ofly have on a large scale and profundity-wide PSTM than measurement capability, it is characterized in that described piezoelectric ceramics (15) stroke is 150 μ m.
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CN2011204243555U CN202305565U (en) | 2011-11-01 | 2011-11-01 | Tunnel scanning microscope with large range and high depth-to-width ratio measurement capacity |
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102384986A (en) * | 2011-11-01 | 2012-03-21 | 浙江大学 | Scanning tunneling microscope having large-scope and high depth-to-width ratio measurement capabilities |
CN103901232A (en) * | 2014-03-13 | 2014-07-02 | 复旦大学 | Low-temperature scanning tunneling microscope using closed-cycle refrigerator to achieve refrigeration |
CN104181335A (en) * | 2013-05-24 | 2014-12-03 | 中国科学院物理研究所 | Scanning tunneling microscope scanning probe head |
CN108873294A (en) * | 2018-07-10 | 2018-11-23 | 长沙健金电子技术有限公司 | A kind of optical tweezer trapped particle of double excitation or the device of cell |
CN110537129A (en) * | 2017-02-15 | 2019-12-03 | 马昆麦崔斯股份有限公司 | Closed mesa Raman spectrometry device |
-
2011
- 2011-11-01 CN CN2011204243555U patent/CN202305565U/en not_active Expired - Fee Related
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102384986A (en) * | 2011-11-01 | 2012-03-21 | 浙江大学 | Scanning tunneling microscope having large-scope and high depth-to-width ratio measurement capabilities |
CN104181335A (en) * | 2013-05-24 | 2014-12-03 | 中国科学院物理研究所 | Scanning tunneling microscope scanning probe head |
CN103901232A (en) * | 2014-03-13 | 2014-07-02 | 复旦大学 | Low-temperature scanning tunneling microscope using closed-cycle refrigerator to achieve refrigeration |
CN103901232B (en) * | 2014-03-13 | 2015-12-09 | 复旦大学 | A kind of low-temperature scanning tunneling microscope utilizing the refrigeration of closed circuit refrigeration machine |
CN110537129A (en) * | 2017-02-15 | 2019-12-03 | 马昆麦崔斯股份有限公司 | Closed mesa Raman spectrometry device |
CN108873294A (en) * | 2018-07-10 | 2018-11-23 | 长沙健金电子技术有限公司 | A kind of optical tweezer trapped particle of double excitation or the device of cell |
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Granted publication date: 20120704 Termination date: 20121101 |