Multiple electron beam device
원문보기
IPC분류정보
국가/구분 |
United States(US) Patent
공개
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0491939
(2002-10-04)
|
공개번호 |
US-0256556
(2004-12-23)
|
우선권정보 |
EP-0123855 (2001-10-05) |
국제출원번호 |
PCT/EP02/11135
(2002-10-04)
|
발명자
/ 주소 |
- Winkler, Dieter
- Adamec, Pavel
- Gohl, Achim
- Banzhof, Helmut
|
대리인 / 주소 |
|
인용정보 |
피인용 횟수 :
0 인용 특허 :
0 |
초록
▼
The invention provides electron multiple beam devices ( 1 ) for probing or structuring a non-transparent specimen ( 20 ) with primary electron beams ( 14 ) with an array of electron beam sources ( 3 ) to generate multiple primary electron beams ( 14 ), an electron sensor ( 12 ) with electron s
The invention provides electron multiple beam devices ( 1 ) for probing or structuring a non-transparent specimen ( 20 ) with primary electron beams ( 14 ) with an array of electron beam sources ( 3 ) to generate multiple primary electron beams ( 14 ), an electron sensor ( 12 ) with electron sensor segments ( 12 a ) to detect electrons of the primary electron beams ( 14 ) and at least one anode ( 7 ) to direct the primary electron beams ( 14 ) towards the electron sensor ( 12 ). The electron sensor ( 12 ) serves to inspect the primary electron beams ( 14 ), calibrate the positions of the primary electron beams ( 14 ) and possibly adjust final focus length ( 13 ) and currents of the primary electron beams before or after a probing or structuring the upper surface ( 20 a ) of a non-transparent specimens ( 20 ). Further, methods to inspect primary electron beams ( 14 ), to adjust final focus lengths ( 13 ) and to calibrate the multiple electron beam device ( 1 ) are provided.
대표청구항
▼
1 . A multiple electron beam device for probing or structuring a non-transparent specimen with primary electron beams with:a field emission cathode array to generate multiple primary electron beams;an electron sensor with electron sensor segments to detect electrons of the primary electron beams;at
1 . A multiple electron beam device for probing or structuring a non-transparent specimen with primary electron beams with:a field emission cathode array to generate multiple primary electron beams;an electron sensor with electron sensor segments to detect electrons of the primary electron beams;at least one anode to direct the primary electron beams towards the electron sensor. 2 . A multiple electron beam device according to claim 1, comprising focusing components to focus the primary electron beams with final focus lengths. 3 . A multiple electron beam device for probing or structuring a non-transparent specimen with focused primary electron beams with:an array of electron beam sources to generate multiple primary electron beams;an electron sensor with electron sensor segments to detect electrons of the primary electron beams;at least one anode to direct the primary electron beams towards the electron sensor;focusing components generating final foci with final focus lengths. 4 . The multiple electron beam device according to claim 1, comprising individually focused components to control the final focus lengths of the primary electron beams individually. 5 . The multiple electron beam device according to claim 1, comprising a support structure to place the non-transparent specimen into the primary electron beams. 6 . The multiple electron beam device according to claim 1, comprising at least one secondary detector to detect secondary particles generated by the primary electron beams at the upper surface of the non-transparent specimen. 7 . The multiple electron beam device according to claim 1, comprising a control unit to read electronic signals from the electron sensor segments. 8 . The multiple electron beam device according to claim 7, wherein the control unit determines what electron sensor segments are hit by a primary electron beam. 9 . The multiple electron beam device according to claim 7, wherein the control unit counts the number of electron sensor segments that are hit by a primary electron beam. 10 . The multiple electron beam device according to claim 7, wherein the control unit determines the electron beam current of a primary electron beam from the electronic signals of the electron sensor segments. 11 . The multiple electron beam device according to of claim 7, wherein the control unit controls the electric or magnetic fields of the focusing focussing components and/or the at least one anode to adjust the primary electron beam positions to desired primary electron beam positions. 12 . The multiple electron beam device according to of claim 7, wherein the control unit controls the electric or magnetic fields of the individually focusing components to adjust the final focal lengths of the primary electron beams to desired final focus lengths individually. 13 . The multiple electron beam device according to of claim 7, wherein the control unit adjusts currents of individual primary electron beams to desired currents. 14 . The multiple electron beam device according to claim 3, wherein the array of electron beam sources is a field emission cathode array and preferably a field emission cathode array integrated on a semiconductor substrate. 15 . The multiple electron beam device according to claim 14, wherein the individually focusing components are integrated onto the field emission cathode array. 16 . The multiple electron beam device according to claim 1, wherein the electron sensor is directly connected to the multiple electron beam device. 17 . The multiple electron beam device according to of claim 1, comprising a magnifying lens which is positioned between the electron sensor and the focusing components that generate the final foci. 18 . The multiple electron beam device according to claim 17, wherein the magnifying lens is part of an electron beam optical system that magnifies the lateral distances D1 between neighboring primary electron beams by a factor larger than the ratio of the pitch of the segments of the electron sensor to the pitch of neighboring electron beam sources. 19 . The multiple electron beam device according to claim 1, wherein the electron sensor is a semiconductor sensor, preferably a Charged Coupled Devide (CCD) or an Active Pixel Sensor (APS). 20 . The multiple electron beam device according to claim 1, wherein the multiple electron beam device is a scanning electron microscope detecting (SEM) or an electron pattern generator. 21 . A method to inspect multiple primary electron beams generated by a field emission cathode array of a multiple electron beam device with the steps of:providing a multiple electron beam device with a field emission cathode array;generating the multiple primary electron beams by means of the field emission cathode array;directing the multiple primary electron beams towards an electron sensor with electron sensor segments; andmeasuring positions of the multiple primary electron beams on the electron sensor by determining positions of the electron sensor segments that are hit by the multiple primary electron beams. 22 . A method to calibrate a multiple electron beam device for probing or structuring a non-transparent specimen with the steps:providing a multiple electron beam device with an array of electron beam sources;generating multiple primary electron beams by means of the electron beam sources;directing the multiple primary electron beams towards an electron sensor with electron sensor segments;measuring positions of the multiple primary electron beams on the electron sensor by determining positions of the electron sensor segments that are hit by the multiple primary electron beams; andgenerating a calibration map relating the measured positions of the multiple primary electron beams to the electron sensor with operational parameters of the multiple electron beam device that direct the primary electron beams to said measured positions on the electron sensor. 23 . The method according to claim 21, wherein the multiple primary electron beams are focused to final foci by means of electric or magnetic focusing fields. 24 . The method according to claim 23, wherein the final focus lengths of the final foci are determined by counting the number of segments that are hit by the primary electron beams. 25 . The method according to of claim 23, wherein whereby the final focus lengths of the primary electron beams are adjusted to desired final focus lengths by means of the electric or magnetic focusing fields. 26 . A method to adjust final focus lengths of focused multiple primary electron beams to desired final focus lengths with the steps:providing a multiple electron beam device with an array of electron beam sources;generating multiple primary electron beams by means of the electron beam sources;directing the primary electron beams towards an electron sensor with electron sensor segments;focusing the primary electron beams by means of electric or magnetic focusing fields;for each primary electron beam determining a number of segments hit by the corresponding primary electron beam; andfor each primary electron beam adjusting the final focus length to a desired final focus length by changing the electric or magnetic focusing fields until a desired number of segments is hit by the corresponding primary electron beam. 27 . The method according to claims 21 , wherein the multiple electron beam device is a multiple electron beam device. 28 . The method according to claim 23, wherein the electric or magnetic focusing fields are generated by individually focusing components. 29 . The method according to claim 21, wherein the lateral distances between neighboring primary electron beams, D1, are magnified by at least one magnifying lens. 30 . The method according to claim 21, wherein the surface of the electron sensor segments is movable towards the upper surface of a non-transparent specimen. 31 . The method according to claim 21, wherein data containing information of the data read from the electron sensor are written onto a data storage device. 32 . The method according to claim 21, wherein the currents of the primary electron beams are measured by means of the electron sensor. 33 . The method according to claim 32, wherein for each primary electron beam the current of the primary electron beam is adjusted to a desired current value.
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