CN1115581C - Heatable sample platform for scanning probe microscope - Google Patents
Heatable sample platform for scanning probe microscope Download PDFInfo
- Publication number
- CN1115581C CN1115581C CN 00130123 CN00130123A CN1115581C CN 1115581 C CN1115581 C CN 1115581C CN 00130123 CN00130123 CN 00130123 CN 00130123 A CN00130123 A CN 00130123A CN 1115581 C CN1115581 C CN 1115581C
- Authority
- CN
- China
- Prior art keywords
- temperature
- support part
- copper billet
- heating
- sample stage
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Images
Landscapes
- Investigating Or Analyzing Materials Using Thermal Means (AREA)
Abstract
The present invention relates to a heatable sample platform which comprises a copper block sample platform, a heating element, a temperature measuring sensor element, a heating and temperature control circuit, etc., wherein the copper block sample platform in which the heating element is arranged is fixed on an upper end cover of a hollow support element, and the temperature measuring sensor element is arranged on the end of the copper block sample platform, which is exposed out of the support element. The outer surface of the copper block sample platform, which is positioned in the support element, is covered with thermal insulating material. A gap is reserved between the bottom of the thermal insulating material and the support element. The bottom end of the support element is fixed on a thermal insulating base. The heatable sample platform has the advantages of simple structure, low price, high precision of temperature measurement, high speed of dynamic response, wide range of temperature change and is suitable for all common scanning probe microscopes with no requirement of any auxiliary equipment.
Description
The present invention relates to a kind of example platform, particularly a kind of heatable sample platform that is used for scanning probe microscopy.This example platform can be elevated to tiny sampler about 1200 ℃ from room temperature, and can keep uniform temperature, with the supporting use of plain scan probe microscope, the Applicable temperature of common probe scanning microscope temperature range about 1200 ℃ can be expanded to by room temperature, and relevant important calorifics function can be increased.
The process of natural science and engineering often huge propelling occurs obtaining owing to new measuring method, and new measurement means is containing new scientific thought and might open up new research forward position.Over past ten years, microscale science of heat and microelectron-mechanical are learned and are studied the especially rise of nanosecond science and technology, have proposed the problem that the size on the nanoscale of material, pattern and hot physical message are measured.And present widely used surveying instrument has scanning probe microscopy, and this scanning probe microscopy can be observed the pattern on the material microscale level, is a kind of critical equipment of obtaining new discovery and impelling this subject to develop in depth.
Scanning probe microscopy (SPM) comprises scanning thermal microscope, scanning tunnel microscope and atomic force microscope etc.Its common ground is that they all adopt a sharp keen probe pinpoint to come near testee, to obtain geometry pattern and other physical quantity of testee in the nanometer space scale.Scanning thermal microscope is wherein a kind of instrument that can be used for studying heat transfer problem in Asia-500-nm yardstick, it is developed by the probe atomic force microscope, adopt a kind of special probe { " nanoscale scanning thermal microscope " the 9th volume in the U.S. " new forward position; experiment thermal conduction study ", the 83-103 page or leaf, 1996 } [Majumdar A., K.Luo, Z.Shi, and J.Varesi, Scanning thermal microscopy atnanometer scales:a new frontier in experimental heat transfer, Experimental Heat Transfer, vol.9, pp.83-103,1996.].Scanning thermal microscope is a temperature sensor to be set in the cantilever probe end scan geometry pattern and the thermal parameter that is heated the surface simultaneously.Atomic force microscope includes a needle point that is loaded on the semi-girder, and sample then places one can be along x, on the piezo-activator that y (plane) and z (vertically) direction move.In case when sample is moved near the needle point several nanometer range, then the interaction force between sample and the needle point (as van der Waals power and electrostatic attraction) will cause the cantilever deflection, this deflection can be amplified by an optical system, specifically collects two joint photodetectors by the laser beam that the cantilever backside reflection is returned and realizes.The deflection of cantilever produces a variance signal A-B because light beam moves; poor formula photo detector signal (A-B) after this modelling so/(A+B) be used to control piezoelectric scanner the moving of vertical direction, to keep a probe and a sample room acting force that constant cantilever deflection is constant in other words.Under the constant force mode, the scanning of sample is laterally being carried out, and peak on the sample or paddy can cause compensatory vertical piezoelectricity to move, and the pattern of sample gets final product imaging thus.Have near the microscope of atom definition with other and to compare, the unique distinction of atomic force microscope is that it can be to any solid material imaging, and is suitable for operating under liquid, gas or vacuum environment.But it can not be used for the measurement of material temperature, so scanning thermal microscope arises at the historic moment.The appearance of scanning thermal microscope makes the research of nanoscale thermal phenomenon become possibility.At present, it has been used to survey those nano electroheating devices.
We know, the macroscopical breakage and the change of properties thereof of material often occur in nanoscale, the character of some material depends on temperature consumingly, thereby understand and the control different temperatures is one of of paramount importance field in microscale science of heat and the nanosecond science and technology research to the influence of material character, thereby development advanced person's measuring technique will greatly be promoted the understanding to related mechanism in this problem.Although in the nano temperature measurement of some common materials, succeed, as scanning thermal microscope being applied to the heat analysis of semiconductor devices, but these class methods will realize alternating temperature and can bring the series of challenges problem, there is very big difficulty in design such as the atomic force microscope example platform, and can increase the difficulty that signal is differentiated.Can will satisfy the nanometer science of heat carried out day by day and the demand of materialogy research at the instrument that a variable temperature scope is observed material geometry and temperature information, have great importance on some emerge science forward positions, achieving the result.Aspect alternating temperature, still rarely have both at home and abroad at present commercial scanning probe microscopy can be in room temperature~1000 ° temperature range alternating temperature, relevant report is detected in the up-to-date scientific literature of delivering the Individual testwas chamber, still is in a kind of state of research and development.Germany Omicron company has developed alternating temperature ultrahigh vacuum scanning probe microscopy (Hou Shimin etc., alternating temperature ultrahigh vacuum scanning probe microscopy, Modern Scientific Instruments, No.3, pp.19-21,2000), can be to the sample imaging between 25K-1100K.This system adopts the liquid helium continuous stream to cross certain heat interchanger and realizes, heat interchanger links to each other with specimen holder by the copper pigtail line, and utilizes heat conduction to reduce sample temperature.Under the mechanical pump effect, liquid helium is sucked out from Dewar flask, and Dewar flask enters liquid helium continuous flow refrigeratory and heat interchanger carries out heat interchange by infusing.The heated sample frame also can make sample change to 1100K from room temperature.This device exists complex structure and higher-priced problem.Therefore, at present in the world among the application of alternating temperature function aspects is in further exploration.Be to realize this purpose, the utility appliance of being equipped with tool alternating temperature function for existing scanning probe microscopy normally, still, auxilliary group of equipment of alternating temperature function is equipped with after, then price is very considerable, for many research and development departments can't bear.
The object of the invention is to provide a kind of heatable sample platform that is used for scanning probe microscopy, this example platform can be elevated to tiny sampler about 1200 ℃ from room temperature, and can keep uniform temperature, can with the supporting use of plain scan probe microscope, do not need to increase bulky, expensive utility appliance, change can expand to 1200 ℃ by room temperature with the Applicable temperature of plain scan probe microscope, and can increase relevant important calorifics function.And simple in structure, cheap, the temperature measurement accuracy height, rapid dynamic response speed, extent of alternating temperature is wide, does not change the structure of existing scanning probe microscopy again, and is fit to and the supporting use of all plain scan probe microscopes.
Embodiment of the present invention are as follows:
The heatable sample platform that is used for scanning probe microscopy provided by the invention, comprise copper billet sample stage 1, heating element 3, thermal insulation material 4, thermometric sensing element 7 and heating element 3 heated heating with temperature control, temperature-adjusting circuit 9, also comprise support member 2 and adiabatic substrate 5, copper billet sample stage 1 is a hollow cylinder or hollow cubic body, heating element 3 is arranged in the hollow cavity of copper billet sample stage 1, the copper billet sample stage 1 that heating element 3 is housed in it fixedly assembly on the upper end cover of hollow support part 2, thermometric sensing element 7 is installed in the end that copper billet sample stage 1 is exposed outside the hollow support part 2, be positioned within the hollow support part 2 on the outside surface of part and be covered with resistant to elevated temperatures thermal insulation material 4, thermal insulation material 4 bottoms and hollow support part 2 leave the gap; Heating element 3 input, output terminal lead-in wire pass aperture 8 on thermal insulation material 4 and hollow support part 2 body walls to stretch out hollow support part 2 external, connect heating, control equalizing network 9, and the bottom of hollow support part 2 is fixed in the adiabatic substrate 5.
Described thermometric sensing element 7 is an occasionally resistance temperature measurement sensing element of thermoelectricity, and the area of copper billet sample stage 1 upper surface is 0.04cm
2To 2cm
2
For making compact conformation of the present invention, the thermal recovery heater strip 6 that adds of its heating element 3 heats, realize different heating powers by changing heater strip 6 electric currents, the temperature of copper billet sample stage 1 is in time returned control piece by thermometric sensing element 7 simultaneously, change size of current according to design temperature, with the temperature constant of assurance sample stage, thereby satisfy the requirement that the hot state of specimen material is adjusted preferably.
Thermometric sensing element 7 of the present invention specifically can be selected thermopair or resistance temperature sensing element for use, is equipped with heating, the temperature-adjusting circuit 9 of different heating watt level, for selecting for use when the needs different temperatures.In general, be subjected to the restriction of scan probe microscopic probe, sample temperature to be determined can not be too high.Whole platform and heating system are simple in structure, and price is very cheap, and performance meets the demands fully, and its biggest advantage is can be directly and the supporting use of existing probe scanning microscope.
Heating element 3 of the present invention can be formed by the resistance wire coiling, and its structure is encapsulated in the copper billet sample stage 1 a series of such elements are integrated as shown in Figure 4, then can change the heating current size as required and realizes the different heats that adds.Copper billet sample stage 1 upper surface area can make 0.04cm as required
2To 2cm
2Thereby, can satisfy the needs that the sample to various area sizes heats, but itself can not be too big, reducing weight, thereby avoid influencing the driving function of probe scanning microscope piezoelectric crystal.In case these heating element 3 energized, because adiabatic all around, heat will reach sample.A crucial part of the present invention also is the 1 welding suspention of copper billet sample stage is contained on the hollow support part 2, even thereby owing to heating can expand itself, but this expansion direction down, thereby any change still almost do not take place in sample surfaces, thereby guarantees the imaging of scanning probe microscopy.Because copper billet sample stage 1 thermal conductivity is very big, and thickness is little, in case energized, heat will reach copper billet sample stage 1 and sample rapidly, and effect is fairly obvious, and obvious intensification was promptly arranged in the several seconds.
The heatable sample platform that is used for scanning probe microscopy provided by the invention, the tiny sampler that is placed on the copper billet sample stage 1 can be elevated to about 1200 ℃ from room temperature, and can keep uniform temperature, with the supporting use of plain scan probe microscope, the Applicable temperature of plain scan probe microscope temperature range about 1200 ℃ can be expanded to by room temperature, and relevant important calorifics function can be increased.It is simple in structure, cheap, and the temperature measurement accuracy height, rapid dynamic response speed, and extent of alternating temperature is wide, does not change the structure of existing scanning probe microscopy, is fit to and the supporting use of all plain scan probe microscopes.
The present invention is further illustrated below in conjunction with the drawings and specific embodiments.
Fig. 1 is a structural representation of the present invention;
Fig. 2 is the structural representation of hollow support part 2;
Fig. 3 is the structural representation of heating element 3;
Wherein: hollow copper billet example platform 1 hollow support part 2 heating elements 3
Thermal insulation material 4, adiabatic substrate 5 thermometric sensing elements 7
Heating, temperature-adjusting circuit 9 apertures 8 resistance wires 6
As seen from the figure, the heatable sample platform that is used for scanning probe microscopy provided by the invention, comprise copper billet sample stage 1, heating element 3, thermal insulation material 4, thermometric sensing element 7 and heating element 3 heated heating with temperature control, temperature-adjusting circuit 9, also comprise support member 2 and adiabatic substrate 5, copper billet sample stage 1 is a hollow cylinder or hollow cubic body, heating element 3 is arranged in the hollow cavity of copper billet sample stage 1, the copper billet sample stage 1 that heating element 3 is housed in it fixedly assembly on the upper end cover of hollow support part 2, thermometric sensing element 7 is installed in the end that copper billet sample stage 1 is exposed outside the hollow support part 2, be positioned within the hollow support part 2 on the outside surface of part and be covered with resistant to elevated temperatures thermal insulation material 4, thermal insulation material 4 bottoms and hollow support part 2 leave the gap; Heating element 3 input, output terminal lead-in wire pass aperture 8 on thermal insulation material 4 and hollow support part 2 body walls to stretch out hollow support part 2 external, connect heating, control equalizing network 9, and the bottom of hollow support part 2 is fixed in the adiabatic substrate 5.
For making compact conformation of the present invention, the heating of its heating element 3 can adopt resistance wire 6 to heat, realize different heating powers by electric current between the change resistance wire 6, the temperature of hollow copper billet sample stage 1 is in time returned control piece by thermopair 7 simultaneously, change size of current according to design temperature, with the temperature constant of assurance sample stage, thereby satisfy the requirement that the hot state of specimen material is adjusted preferably.
Thermometric sensing element 7 of the present invention can be selected thermopair or resistance temperature sensing element for use, and is equipped with the temperature-adjusting circuit of different heating watt level, for selecting for use when the needs different temperatures.In general, be subjected to the restriction of scan probe microscopic probe, sample temperature to be determined can not be too high.
Compact conformation of the present invention, simple, low price, and performance meets the demands fully can be directly and the supporting use of existing scanning probe microscopy.
Heating element 3 can be formed by the resistance wire coiling, and its structure is encapsulated in the hollow copper billet sample stage 1 a series of such elements are integrated as shown in Figure 2, then can change the heating current size as required and realizes the different heats that adds.The area of hollow copper billet sample stage 1 upper surface can make 0.04cm as required
2To 2cm
2Thereby, can satisfy the needs that the sample to various area sizes heats, but in order not influence the driving function of scanning probe microscopy piezoelectric crystal, hollow copper billet sample stage 2 volumes can not be too big.In case heating element 3 energized, because adiabatic all around, heat will reach sample.A crucial part of the present invention also is hollow copper billet sample stage 1 welding suspention is contained on the hollow support part 2, even thereby owing to heating can expand itself, but this expansion direction down, thereby any change still almost do not take place in sample surfaces, thereby guarantees the imaging of probe scanning microscope.Because hollow copper billet sample stage thermal conductivity is very big, and thickness is little, in case energized, heat will reach sample stage and sample rapidly, and effect is fairly obvious, and obvious intensification was promptly arranged in the several seconds.
Processing of the present invention and manufacture step and be:
Step 1: in hollow copper billet sample stage 1, have hollow cavity, insert heating element 3 in the chamber and after fixing, the thermal insulation material 4 of pasted with high temperature-resistant on the outer wall of the bottom of hollow copper billet sample stage (major part), the upper cover plate with hollow copper billet sample stage and hollow support part 2 adopts dot welding method to fix again;
Step 2: with the chamber wall and the bottom welding of hollow support part 2, the adiabatic base material 5 of lower end bonding of hollow support part 2;
Step 3: the assembly in assembly and the step 2 in the step 1 is packaged together by Fig. 1, and the resistance wire 6 of heating element 3 is drawn by the aperture on the chamber wall of hollow support part 2.
Here, temperature sensor 7 is that example is illustrated with thermopair (can adopt the resistance temperature sensing element), promptly on hollow copper billet sample stage 1, have micropore by calibration position, micro-pore diameter is about about 100 μ m, thermocouple junction is fixed in the micropore place, and to measure this position temperature, the signal input part of data collecting instrument is then drawn and be connected in to the wire harness of thermopair, and data collecting instrument connects on the computing machine, so promptly forms the temperature sensor 7 that the position is determined.Like this, the temperature signal that hollow copper sample platform 1 is collected outputs to the signal input part of data collecting instrument by thermopair with signal, and then transfers in the computing machine, and whether the control program decision of being worked out by computing machine changes the heating current size.According to the requirement of sample temperature to be tested, heating voltage can be regulated, so that the quantity of heat given up of different sizes to be provided.
From the above mentioned, the temperature sensor 7 that the present invention adopts derives from thermopair, and its response speed is very fast, and precision is higher, it is cheap that price then is tending towards, and the making of heater circuit, sample stage etc. is relatively easy, data acquisition and handle very convenient, no complicated circuit, simple in structure, the hot state ratio of thermometric and assess sample is easier to, and extent of alternating temperature is wide, be suitable for studying the character and the nanotopography of material under the different temperatures, and even carry out the mensuration of relevant thermophysical property.
During use, the heatable sample platform that is used for scanning probe microscopy of the present invention is placed the raw sample platform of plain scan probe microscope, sample is held on the hollow copper billet sample stage 1 of the present invention, opens computing machine and data collecting instrument, and heater circuit, note the temperature level of relevant thermopair, set the temperature of sample to be heated then, open heater circuit, both can begin the intensification of sample, when arriving predetermined temperature, heater circuit can be kept the temperature constant of sample stage.Can begin the imaging of scanning probe microscopy this moment.If need to change sample temperature, only need to change the heating current size, thereby reach new sample temperature.Open heater circuit, behind certain hour, reach certain stationary value, open computing machine and data collecting instrument, note the temperature of measured continuous variation,, thus, can realize the imaging of the specimen material pattern under the different temperatures until basicly stable.Can study temperature or heating influence thus, and measure relevant important hot rerum natura material pattern and relevant physical property.
Claims (4)
1. heatable sample platform that is used for scanning probe microscopy, comprise copper billet sample stage (1), heating element (3), thermal insulation material (4), thermometric sensing element (7) and heating element (3) heated heating with temperature control, temperature-adjusting circuit (9), also comprise support member (2) and adiabatic substrate (5), copper billet sample stage (1) is a hollow cylinder or hollow cubic body, heating element (3) is arranged in the hollow cavity of copper billet sample stage (1), be equipped with in it heating element (3) copper billet sample stage (1) (Gu) decide assembly on the upper end cover of hollow support part (2), thermometric sensing element (7) is installed in the end that copper billet sample stage (1) is exposed outside the hollow support part (2), be positioned within the hollow support part (2) on the outside surface of part and be covered with resistant to elevated temperatures thermal insulation material (4), the gap is left with hollow support part (2) in thermal insulation material (4) bottom; Heating element (3) input, output terminal lead-in wire pass aperture (8) on thermal insulation material (4) and hollow support part (2) body wall, and to stretch out hollow support part (2) external, connect heating, temperature-adjusting circuit (9), the bottom of hollow support part (2) is fixed in the adiabatic substrate (5).
2. by the described heatable sample platform that is used for probe scanning microscope of claim 1, it is characterized in that: described thermometric sensing element (7) is an occasionally resistance temperature measurement sensing element of thermoelectricity.
3. by the described heatable sample platform that is used for probe scanning microscope of claim 1, it is characterized in that: described heating element (3) is with adopting resistance wire (6) heating.
4. by the described heatable sample platform that is used for probe scanning microscope of claim 1, it is characterized in that: the area of described copper billet sample stage (1) is 0.04cm
2To 2cm
2
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN 00130123 CN1115581C (en) | 2000-09-29 | 2000-09-29 | Heatable sample platform for scanning probe microscope |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN 00130123 CN1115581C (en) | 2000-09-29 | 2000-09-29 | Heatable sample platform for scanning probe microscope |
Publications (2)
Publication Number | Publication Date |
---|---|
CN1344952A CN1344952A (en) | 2002-04-17 |
CN1115581C true CN1115581C (en) | 2003-07-23 |
Family
ID=4593980
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN 00130123 Expired - Fee Related CN1115581C (en) | 2000-09-29 | 2000-09-29 | Heatable sample platform for scanning probe microscope |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN1115581C (en) |
Families Citing this family (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101665236B (en) * | 2009-09-08 | 2012-03-21 | 北京航空航天大学 | Controllable temperature sample table with controllable temperature range of 77K to 400K |
EP2555221B1 (en) | 2011-08-03 | 2013-07-24 | Fei Company | Method of studying a sample in an ETEM |
CN103048300A (en) * | 2012-12-17 | 2013-04-17 | 江苏大学 | Confocal laser scanning microscope |
CN103308379B (en) * | 2013-05-16 | 2015-08-19 | 中国科学院化学研究所 | A kind ofly use the microscope heating arrangement of common object lens and corresponding heating system |
CN106405812A (en) * | 2016-11-07 | 2017-02-15 | 孙家仁 | Simple manufacturing method of electric thermostat on microscope objective table |
CN106596244B (en) * | 2016-12-14 | 2023-06-23 | 宁海德宝立新材料有限公司 | Temperature-control sample stage |
CN106771372A (en) * | 2017-01-18 | 2017-05-31 | 中国科学院深圳先进技术研究院 | Thermoelectricity detecting system and thermoelectricity detection method |
-
2000
- 2000-09-29 CN CN 00130123 patent/CN1115581C/en not_active Expired - Fee Related
Also Published As
Publication number | Publication date |
---|---|
CN1344952A (en) | 2002-04-17 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US9696270B1 (en) | Thermal conductivity measurement apparatus and related methods | |
King et al. | Heated atomic force microscope cantilevers and their applications | |
JPS62261902A (en) | Fine surface shape measuring device | |
Gmelin et al. | Sub-micrometer thermal physics–An overview on SThM techniques | |
Spiece et al. | Improving accuracy of nanothermal measurements via spatially distributed scanning thermal microscope probes | |
JP4595073B2 (en) | Thermoelectric material measuring device | |
Wielgoszewski et al. | Scanning thermal microscopy (SThM): how to map temperature and thermal properties at the nanoscale | |
Janus et al. | Novel SThM nanoprobe for thermal properties investigation of micro-and nanoelectronic devices | |
CN1115581C (en) | Heatable sample platform for scanning probe microscope | |
Park et al. | Frequency-dependent electrical and thermal response of heated atomic force microscope cantilevers | |
Bontempi et al. | Quantitative thermal microscopy using thermoelectric probe in passive mode | |
Wu et al. | A bi-material microcantilever temperature sensor based on optical readout | |
Bodzenta et al. | Quantitative thermal measurement by the use of scanning thermal microscope and resistive thermal probes | |
CN2443365Y (en) | Sample table capable of rising temp for scanning probe microscope | |
Majstrzyk et al. | Thermomechanically and electromagnetically actuated piezoresistive cantilevers for fast-scanning probe microscopy investigations | |
CN104111268A (en) | Device for in-situ heating of atomic force microscope conducting probe and in-situ characterization of nanometer Seebeck coefficient | |
Liu et al. | Near-field radiation analysis and thermal contact radius determination in the thermal conductivity measurement based on SThM open-loop system | |
Thiery et al. | Thermal contact calibration between a thermocouple probe and a microhotplate | |
Świadkowski et al. | Near-zero contact force atomic force microscopy investigations using active electromagnetic cantilevers | |
Tabib-Azar et al. | Transient thermography using evanescent microwave microscope | |
Doumouro et al. | Quantitative measurement of the thermal contact resistance between a glass microsphere and a plate | |
JP3364531B2 (en) | Optical lever scanning probe microscope and atomic force microscope | |
Janus et al. | Design, technology, and application of integrated piezoresistive scanning thermal microscopy (SThM) microcantilever | |
KR101240399B1 (en) | Scanning thermal microscope and temperature profiling method using the same | |
Gu et al. | Imaging of thermal conductivity with sub-micrometer resolution using scanning thermal microscopy |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C10 | Entry into substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
C06 | Publication | ||
PB01 | Publication | ||
AR01 | Abandonment of patent right to avoid double patenting |
According to article 9 of the patent law and article 13 of the detailed rules for the implementation of the patent law: 130123.3 of the invention patents in this issue as a notice of authorization, and at the same time corresponding to the 257823.9 utility model patent to be given up, and in the 19 volume of the 30 issue of the new type of communique on the patent right to abandon the announcement. |
|
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
C19 | Lapse of patent right due to non-payment of the annual fee | ||
CF01 | Termination of patent right due to non-payment of annual fee |