Classifications

• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
  • H01J37/26—Electron or ion microscopes; Electron or ion diffraction tubes
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
  • H01J37/02—Details
  • H01J37/244—Detectors; Associated components or circuits therefor
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J37/00—Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
  • H01J37/26—Electron or ion microscopes; Electron or ion diffraction tubes
  • H01J37/28—Electron or ion microscopes; Electron or ion diffraction tubes with scanning beams
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J2237/00—Discharge tubes exposing object to beam, e.g. for analysis treatment, etching, imaging
  • H01J2237/004—Charge control of objects or beams
  • H01J2237/0041—Neutralising arrangements
  • H01J2237/0044—Neutralising arrangements of objects being observed or treated
  • H01J2237/0045—Neutralising arrangements of objects being observed or treated using secondary electrons
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J2237/00—Discharge tubes exposing object to beam, e.g. for analysis treatment, etching, imaging
  • H01J2237/244—Detection characterized by the detecting means
  • H01J2237/2448—Secondary particle detectors
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J2237/00—Discharge tubes exposing object to beam, e.g. for analysis treatment, etching, imaging
  • H01J2237/26—Electron or ion microscopes
  • H01J2237/2602—Details
  • H01J2237/2605—Details operating at elevated pressures, e.g. atmosphere

Definitions

• Particle-optical Device ana ue ⁇ ec ⁇ ion ivieans
• the invention relates to a particle-optical apparatus comprising a sample holder arranged for receiving a sample, a particle source arranged for producing a primary beam of first electrically charged particles along an optical axis for irradiating said sample, first detection means arranged for detecting electrons such as secondary electrons emanating from the sample due to said irradiation, a detection space formed by at least said sample holder and said first detection means, and an immersion lens arranged for providing a magnetic field for focusing the primary beam in the vicinity of the sample holder, wherein said first detection means are arranged for providing an electric field in the detection space, and wherein the detection space is arranged for comprising a gas,
• Such devices are better known by the name Environmental Scanning Electron Microscopes (ESEM), and are based on the principle of Scanning Electron Microscopes (SEM).
• SEM Scanning Electron Microscopes
• a region of a sample that is to be investigated is probed by a primary beam of electrically charged particles (generally electrons) that move along an optical axis of the device.
• electrically charged particles generally electrons
• the charged particles incident on the sample causes the liberation of other charged particles in the sample, which emanate from the sample with a certain kinetic energy.
• the energy of these secondary particles which is substantially lower than the energy of the particles in the primary beam, provides information on the nature, structure and composition of the sample.
• a SEM is often provided with a secondary electron detection apparatus, which can detect these liberated particles.
• the secondary electron detection apparatus is provided with an electrode that is maintained at a positive voltage, and if it is presumed that the secondary particles liberated from the sample are (negatively charged) secondary electrons, then these secondary electrons will move toward the electrode.
• the secondary electrons captured by the electrode produce a current in the detector, which current can be amplified and can yield the necessary information about the sample. Because the primary beam from the particle source probes a region of the sample, it is possible to obtain an image of the sample by compiling the information obtained with the aid of the detector. It will be apparent that, in connection with the quality of the image thus obtained, particularly the speed with which the image is recorded and the signal-to-noise ratio (SNR), it is useful to have the detected current as large as possible.
• SNR signal-to-noise ratio
• an ESEM the sample that is to be investigated is placed in an atmosphere of a gas having a pressure between 0.1 Torr (13 Pa) and 50 Torr (6575 Pa), whereas in a conventional SEM the sample is located in vacuum.
• the advantage of an ESEM as compared to a conventional SEM is that the ESEM offers the possibility to form electron-optical images of moist or non-conducting samples (for example: biological samples, moist samples, plastics, ceramic materials or glass fibers) which, under the usual vacuum conditions in the conventional SEM, would be difficult to image.
• the ESEM provides the possibility of maintaining the sample in its natural state, without having to be subjected to the disadvantageous effects of drying, freezing or vacuum coating, which are normally necessary in studies using conventional SEMs.
• Another advantage of the employed gaseous atmosphere is the dissipation of the surface charge accumulating on the sample as a result of irradiation (assuming the sample to be a non-conducting sample), as a result of which the resolving power of the microscope is increased.
• the use of a gaseous atmosphere in an ESEM also makes improved detection means possible.
• the liberated secondary electrons that move in the direction of the secondary electron detector will collide en route with gas molecules present in their path. This collision will result in the liberation of new electrons (so called daughter electrons) from the gas molecules, which will also move in the direction of the secondary electron detector.
• an ESEM is disclosed wherein the primary beam from the particle source is focused on the sample by means of an immersion lens.
• the immersion lens consists of a magnetic dipole whose poles are located on opposite sides of the sample chamber formed by the sample holder and primary beam source.
• a magnetic field is present in the sample chamber.
• the secondary electrons liberated from the sample will be influenced by the magnetic field while on their way to the detector, as a result of which they will follow a helical path. It is claimed that in this way, the distance traversed by the secondary electrons is greatly increased, so that the collision probability proportionately increases and the amplification factor of the detection apparatus increases.
• a disadvantage of the disclosed device described here above is that, in the given configuration, the ⁇ lectrons follow a helical path around an axis that extends parallel to a magnetic field.
• the distance traversed by the electron from the sample to the detector is directly dependent upon the distance between the detector and the sample in the direction of the magnetic field.
• the distance traversed by the primary beam through the sample chamber (and thus through the gaseous atmosphere) shall also be large. As a result of this, scattering of the primary beam will increase. An increased amplification factor for the detection apparatus is thus achieved at the expense of the resolving power of the illustrated device.
• said first detection means and said immersion lens are arranged for providing the electric field and the magnetic field such that the detection space comprises a first portion in which the electric field is oriented transverse to the magnetic field. It can be shown that the motion of the low energy electrons in this field structure can create a large amplification factor, provided that certain values of electric field and magnetic field are present. It can further be shown that this large amplification can take place even with a low pressure of gas, which further reduces the scattering of the primary beam.
• the invention makes use of the principle that the resultant force F (by
• the vector F is meant here) on an electrically charged particle, such as an electron, moving through a magnetic field and an electric field is comprised of the electrical force F E and the magnetic force F B on the particle.
• the electrical force F E is, dependent on the charge of the particle, parallel or anti-parallel to the electric field E , and the magnetic force is oriented perpendicular to the velocity v of the particle and the magnetic flux B .
• the direction of the magnetic force F B is further determined by the polarity of the charge of the particle (positive/negative).
• the electrical force and magnetic force are given by:
• the present invention makes use of the motion followed by an electron that starts from rest (or low energy) in a magnetic field that is orthogonal to an electric field.
• the electrons will follow a so called cycloidal path and the kinetic energy of the electron will cycle repeatedly from the starting energy to a higher energy and then back to the original energy. This cycle will repeat indefinitely in high vacuum.
• the electron may collide with a gas molecule. If the kinetic energy of the electrons exceeds the ionization energy of the gas present in the detection space, then the electron is capable of liberating another electron (called a daughter electron) in a collision with a gas molecule.
• the electric field may have radial symmetry, and the electron will follow a generally circular path, combined with the cycloidaf motion.
• the same large amplification may occur.
• This radial electric field can be conveniently provided by an annular electrode, which may also serve as the signal detector. It can further be shown that this large amplification factor can occur at low pressures of the gas.
• the distance traversed by the particle between the sample and the detector is not dependent upon the working distance traversed by the primary beam of primary electrons through the detection space.
• the distance traversed by the particle is dependent upon the distance between the optical axis and the most closely located point of the detector electrode. Performing the detection technique described will not be at the expense of the resolving power of the particle-optical apparatus.
• the electric field must have a component E that is perpendicular to the magnetic field B of sufficient magnitude to bring electrons in the cycloidal motion to a kinetic energy that is higher than the ionization energy of the gas molecule. From this, an average person skilled in the art will be able to calculate those parameters that are of importance with regard to the electric field and magnetic field.
• a particle-optical device in which the first detection means and the immersion lens are further arranged for providing the electric field and the magnetic field such that the detection space comprises a second portion in which the electric field and the magnetic field are parallel.
• the electric field has a component E that is parallel to the magnetic field B then a particle that has a random velocity that is not completely parallel to the magnetic flux B will follow a helical path.
• An explanation for this is that as a result of the electrical force F E the particle will be accelerated uniformly in the direction of the electric field F E .
• the component of the velocity V"of the particle that is perpendicular to the magnetic flux B will experience a force F B that is perpendicular to the velocity and the magnetic field. This component of the velocity V"of the particle perpendicular to the magnetic flux B will consequently vary continually in direction.
• the particle will accordingly describe a helical motion around an axis that is oriented in the direction of the electric field E . If the electric field E can be made to change from positive to negative then the secondary electrons will oscillate backwards and forwards while also describing the helical motion due to the magnetic field. The combination of these two motions will greatly increase the path of the electrons in the gas, and thereby increase the amplification of the signal. As a result of this, the detector of the particle-optical device of the present invention will become more sensitive.
• the first detection means comprise a first electrode that is arranged for providing the electric field and for detecting the secondary and daughter electrons, whereby the first electrode comprises a central opening which is symmetrically arranged around the optical axis.
• This embodiment provides a simple set-up for generating a radially symmetric electric field around the optical axis.
• the set-up wherein the sample holder in which the sample is located during operation is disposed in extension of the optical axis, will, when the dimensions of the central opening are suitably chosen, generate an electric field that, in the vicinity of the detector, comprises a large component perpendicular to the optical axis, and, furthermore, in the vicinity of the sample holder, will comprise a large component parallel to the optical axis.
• the detection space comprises regions in which the electric and magnetic field are parallel as well as regions in which the electric and magnetic field are directed perpendicular or transverse to one another. In this manner, the invention can be applied in an easy manner in a particle-optical device.
• a particle-optical device further comprises second detection means that are arranged for detecting second charged particles, such as ions, that are formed in the gas due to interactions between the gas and the electrons.
• second detection means that are arranged for detecting second charged particles, such as ions, that are formed in the gas due to interactions between the gas and the electrons.
• the detection means comprise a second electrode that is located between the sample and the first detection means, whereby the second electrode comprises a central opening that is symmetrically disposed around the optical axis.
• Such an electrode offers the advantage that it does not asymmetrically disturb the radial electric field of the first electrode. Since electrons are usually more " mobile than ions, in view of their mass, the placement of the second electrode between the first electrode and the sample will yield the advantage that ions will be more easily captured by the second electrode. The positive ions will thus collide with the second electrode, whereby they will be neutralized by recombination and will thus cause a signal which may be measured from the second electrode.
• the sample holder comprises a third electrode, and the third detection means are at least comprised by the sample holder.
• some of the positively charged ions from the gas are collected by the sample holder. In this manner, a current can be generated in the third detector, which provides the desired signal.
• Another embodiment of the invention further comprises fourth detection means arranged for detecting photons that have been liberated as a result of interactions between the gas and the electrons.
• photons may be generated that can be detected by fourth detection means.
• the number of detected photons i.e. the intensity of the detected light, is proportional to of the number of collisions that have taken place between secondary electrons and gas molecules. Consequently, the detected light intensity is directly related to the secondary electron signal from the sample and the signal from the first detector.
• the detection of these photons provides information on the sample, which information may be used in signal processing and image formation.
• a preferred embodiment of the present invention further comprises means for the provision of a signal based on a combination of at least two signals provided by the first, second, third and fourth detection means.
• a particle-optical device comprises means that are embodied to electrically bias the sample with a negative bias. In such a scenario the electric field between the sample and the first detector will increase, which will increase the amplification in the gas.
• the present invention relates to detection means comprising a ring-shaped electrode and amplification means arranged for use as first detector means in a particle-optical apparatus according to a first aspect of the invention.
• the present invention relates to a method of detecting electrons in a particle-optical apparatus wherein a sample is irradiated by a primary beam of charged particles and secondary electrons are liberated from said sample by said irradiation, wherein said secondary electrons are accelerated towards detection means and a detection space is at least formed by said detection means and said sample, said detection space comprising a gas, and wherein an immersion lens provides a magnetic field in said detection space, wherein said electric field and said magnetic field are provided such that the detection space comprises at least a portion wherein the electric field is oriented transverse to the magnetic field.
• Figure 1a renders a schematic depiction of path of an electron propagating through a magnetic and an electric field, whereby the electric field is transverse to the magnetic field in a vacuum.
• Figure 1b further depicts an electron propagating through the fields in a gaseous environment, showing a collision between the electron and a gas molecule, thereby producing a daughter electron.
• the schematic further depicts the subsequent path of both electrons.
• Figure 2a shows the field from a magnetron where the electric field is transverse to the magnetic field and the electric field is radially symmetric.
• Figure 2b depicts the motion of an electron in this field in a vacuum, and
• Figure 2c further depicts the motion of an electron in this field in a gas.
• Figure 3 renders a schematic depiction of the path of an electron propagating through a magnetic and an electric field, whereby the magnetic field and the electric field are parallel to one another, and the electron has initial velocity components parallel and perpendicular to the fields.
• Figure 4a depicts an electric potential that increases and then decreases again along a z axis.
• FIG. 4b depicts the motion of an electron in the potential gradient of Figure 4a in a gaseous environment.
• Figure 5 is a schematic depiction of a detection space of an embodiment of a particle-optical device according to the present invention, in which electric and magnetic field lines are depicted;
• Figure 6 is a schematic depiction of an embodiment of the present invention.
• Figure 7 is a graph showing gas amplification as a function of anode voltage for an ESEM detector without a magnetic field in the detector space and for an ESEM detector used with an immersion lens that provides a magnetic field.
• Figure 8 is a schematic depiction of another embodiment of the present invention.
• Figure 1 a is a schematic depiction of the motion of an electron 1 that starts with zero velocity at k and moves under the influence of electric field E (which is parallel to the Y axis) and magnetic field B (which is perpendicular to the page, and directed into the page).
• E which is parallel to the Y axis
• B which is perpendicular to the page, and directed into the page.
• Figure 1b depicts the situation where the electron is in a gaseous environment. As the electron follows the cycloidal path it will eventually collide with a gas molecule, depicted as point q. If the electron energy at q exceeds the ionization energy of the gas molecule then the gas molecule will be ionized and another electron is liberated. This second electron is designated a daughter electron 3.
• the original electron 1 and the daughter electron 3 will both start from q and will undergo the cycloidal motion shown as 4. These two electrons may each ionize further gas molecules, thereby causing a cascade multiplication. This mechanism is exploited in the primary claim of the present invention.
• Figure 2a shows a cylindrical magnetron field configuration.
• the Figure depicts the situation where the outer electrode is at a more positive voltage than the inner electrode, creating the electric field E which is radially symmetric.
• E which is radially symmetric.
• B which is perpendicular to the page. It can be shown that an electron starting from rest in a vacuum between the electrodes will accelerate towards the outer electrode and may undergo a motion similar to the cycloid shown in Figure 1 , but while at the same time travel in a generally curved path around the inner electrode. This path is depicted as 7 in Figure 2 b.
• the generation of daughter electrons and the subsequent cascade amplification will occur provided that certain values of E and B are present.
• the maximum energy of the electron in the cycloidal motion is given by 2*m*(E/M) ⁇ 2/q, where m is the mass of an electron and q is the charge of an electron. If this maximum energy is greater than the ionization energy of the gas, then an ionizing event can occur and a daughter electron can be generated.
• B there is a Critical value of E that is required. In a circular symmetric electric field the value of E varies with radius, and in order to obtain a large amplification the Critical value must be provided over a large part of the detection space.
• a radial electric field may be provided by various different structures.
• a ring electrode or a plate electrode with a circular hole will both provide a radially symmetric electric field.
• the electric field produced by a ring or a plate electrode will produce the preferential amplification described.
• the ring or plate may be placed symmetrically about the charged particle beam which minimizes the effect of the electric field on the charged particle beam.
• the required axial magnetic field may be provided by various different structures.
• a suitable magnetic field can be provided by a so called immersion lens of a charged particle beam apparatus, or within the polepiece of a so called pinhole lens of a charged particle beam apparatus, or provided by the so called single pole lens of a charged particle beam apparatus.
• Figure 3 shows the case in which an electron 15, which may, for example, be a secondary electron liberated by an electron primary beam from a sample, propagates through an electric and a magnetic field, whereby the electric field strength 18 and the magnetic field strength 17 are principally parallel to one another and in the direction of the Z axis as shown by coordinate axes 5.
• the electric field strength 18 and the magnetic field strength 17 have parallel components that are much larger than the components that are perpendicular to one another.
• an electron 15 has, for example, an initial velocity 16, which initial velocity 16 has a component 16' parallel to (but, for example, oppositely directed to) the electric field 18 and the magnetic field 17, whereby the velocity 16 further has a component 16" that is perpendicular to the electric field and the magnetic field 17.
• the electric field 18 will, at the outset, uniformly accelerate the electron 15 in a direction opposite to that of the electric field 18.
• the component 16" of the velocity that is perpendicular to both fields 17 and 18 will ensure that an interaction arises with the magnetic field, giving rise to a magnetic force on the electron that is continually perpendicular to the velocity component 16".
• the particle will traverse a helical or screw-thread-like path.
• the radius of this path will be determined by the so-called Larmor radius, with which the average skilled artisan is familiar.
• Figure 4a depicts a situation where an electric potential 9 increases along the Z axis to a maximum value V and then decreases.
• An electron 10, subject to this potential will at first be accelerated by the electric field created by the potential, then will decelerates again, and then reverse direction. That is, the electron 10 will, if unobstructed, oscillate around the point or plane of highest potential.
• the path followed by the electron in a gaseous environment is depicted by 12 in Figure 4b.
• the electron will oscillate in the electric field but the amplitude will decrease. If the electric field is sufficiently intense then the electron may gain sufficient kinetic energy to cause a gas molecule to be ionized during the collision, thereby generating a daughter electron.
• the daughter electron may also be accelerated by the electric field and a cascade amplification may occur.
• Figure 5 schematically depicts a detection space 20, which detection space is formed at least by a ring-shaped anode 32 (depicted in cross section) and a schematically depicted base structure 31 of a particle-optical device comprising a sample 41.
• a (non-depicted) electron primary beam is generated by a (non-depicted) electron source, whose edge (of which only the extremity 30 is shown in the figure) forms a first pole of a magnetic dipole.
• the base structure 31 of the particle-optical device may form the second pole of the magnetic dipole.
• a magnetic field arises that is schematically depicted by the magnetic field lines 35.
• Anode 32 is typically biased at a positive potential between 10 V and 2000V.
• the primary beam opening 33 and the base structure 31 are typically biased at ground potential. These conditions typically provide an electric field that is schematically depicted by the electric field lines 34. It can be shown that the potential distribution along the Z axis has the desired form depicted in Figure 4.
• an electron primary beam (not depicted), which is focused by the magnetic field 35, passes through the primary beam opening 33 of the electron source, traverses the detection space 20, and impinges on sample 41 that is located on top of the base structure 31.
• Located in the illustrated detection space 20 is a subspace in which the electric field lines 34 and the magnetic field lines 35 are principally perpendicular to one another.
• this subspace is principally formed by the opening in the ring-shaped anode 32.
• the detection space 20 further comprises a subspace in which the electric and magnetic field lines are oriented principally parallel to one another.
• This subspace is at least bordered by the base structure 31. In the depicted example, such a subspace is present in the vicinity of the extremity 30 of the electron source.
• the schematic depiction given in Figure 5 has a radial symmetry about a (non-depicted) primary beam axis that traverses the primary beam opening and is perpendicular to the base structure 31.
• the motion of the low energy electrons in this field structure can create a large amplification factor, provided that certain combinations of values are present for the electric field and magnetic field.
• the anode hole size is a factor in determining the strengths of the parallel and transverse components of the electric field. If the hole in the anode is too small, then the amplification will be enhanced by the magnetic Penning mechanism, but the magnetron mechanism will be degraded or absent because the electric field will not achieve the critical value described above with respect to Figure 2. If the hole is too big, the amplification enhanced by the magnetic Penning mechanism may be absent, although the magnetron amplification may be increased.
• Figure 7 shows a graph of the gas amplification as a function of anode voltage. Gas amplification is the number of charges detected for each secondary electron.
• Line 70 shows the amplification of an ESEM detector in the absence of a magnetic field in the detection space
• line 72 shows the amplification of an ESEM detector used with a magnetic immersion lens that provides a magnetic field in the detection space.
• Line 72 is comprised of a first region 73, in which the amplification process is characterized primarily by a Penning mechanism; a second region 74 in which the amplification is characterized by a combination of a magnetron mechanism and a Penning mechanism; and a transition region 75.
• the slope 76 of the Penning mechanism region 73 is significantly less than the slope of the slope 77 of the combined mechanism region 74.
• the combined mechanism can provide gas amplification greater than about 1000, greater than about 2000, greater than about 5000, and greater than about 10,000, all with anode voltages below about 350 V or about 400 V.
• Embodiments of the invention that operate above transition region 75 and in the combined region 74 provide substantially greater amplification than prior art detectors that operate solely in Penning region 73.
• Line 72 shows data from one embodiment, and skilled persons will recognize that that other embodiments will produce different amplification and different slopes.
• the detection space 20 depicted in Figure 5 may provide the conditions for both the magnetic Penning mechanism, and the conditions for the magnetron, provided that appropriate values for the dimensions are chosen, and provided that appropriate values of potential on anode 32, and magnetic field B are chosen for the given anode hole size.
• the amplification of this detection space can be very high due to the multiplicative effect of the amplification using the magnetic Penning mechanism and magnetron mechanism.
• a set of conditions that provides conditions for both the magnetic Penning mechanism and for the magnetron mechanism includes an anode hole size about 3 mm, a magnetic field of up to about 0.3 Tesla, an anode potential greater than about 400 V, and a gas pressure of about .3 Torr. These conditions are known to produce an amplification that is much greater than any previous ESEM detector at 400V. Typical operational pressures are between 0.1 Torr and 0.7 Torr.
• the detection space 20 depicted in Figure 5 is shown once again in a schematic depiction of the embodiment of the present invention in Figure 6. Parts that have a similar functionality to that in Figure 5 are indicated using correspondingly similar reference numerals. Also visible in the depicted embodiment is an ion plate 36, which, if desired, can be biased or can be earthed. Maintenance of the pressure difference between the vacuum atmosphere in the electron source and the necessary atmosphere in the detection space 20 occurs by means of the separation diaphragm 37. The primary beam opening 33 is now part of the separation diaphragm 37. Furthermore, the ring-shaped electrode 32 is connected to an amplifier 38, which is biased to provide the potential on anode 32.
• Amplifier 38 produces a signal at the output 39 that is proportional to the number of detected electrons.
• a primary beam generated by the (non-depicted) electron source will pass along the optical axis 40, through primary beam opening 33, across detection space 20 and impinge on a sample 41 , which sample is temporarily fixed to a sample holder 42.
• the (non-depicted) electric field generated by the ring-shaped anode 32, and the (non-depicted) magnetic field generated by the magnetic dipole formed by the wall of the electron source 30 and the base structure 31 will ensure that, in analogy to Figure 5, a subspace is formed in the vicinity of the sample 41 , in which subspace the electric field and the magnetic field are parallel to one another.
• Each secondary electron liberated by the primary beam from the sample 41 can, as a consequence of the so called “magnetic Penning " mechanism shown in Figure 4 generate a number of daughter electrons in the center of the anode 32. Collisions with the gas cause these electrons to depart from the center of the anode and they then undergo the magnetron motion.
• each daughter electron generated using the magnetic Penning mechanism may generate more daughter electrons as a result of the magnetron motion.
• a two stage amplifier is formed so that a very large number of electrons may reach the anode for each original secondary electron.
• ions generated in the gas may be used may be used to counteract charging of the sample due to the charged particle beam.
• the generation of daughter electrons using the magnetic Penning mechanism and magnetron mechanism will also generate positively charged gas ions. Some of these ions will migrate to the separation diaphragm 37 and some will migrate towards the sample 41. Some of the ions that migrate to the sample are required to dissipate the charge induced in the sample due to the charged particle beam. However, the high amplification factor of this detection volume may generate a surplus of ions. These surplus gas ions may be collected by an electrode between the sample and the anode. Such an electrode could take the form of a grid, a wire, a set of wires, or a plate such as the ion plate 36. The electrode may be electrically biased, or at ground potential.
• the distance between the base structure 31 and the wall of the electron source 30 can be chosen to be so small that the subspace in which the electric and magnetic field are principally parallel to one another is very small, or even absent.
• the detection space is therefore very "flat", and the electric and magnetic field will be principally transverse to one another.
• the secondary electrons liberated from the sample 41 shall thus immediately be subjected to circumstances under which the electric field and the magnetic field are principally perpendicular to one another.
• the amplification using the magnetic Penning mechanism may be absent but the detector combination 32, 38, 39 can still achieve a large amplification factor due to the magnetron, which is sufficiently large to produce the desired signal at the output of the detector 39, while the working distance -being the distance that the electron primary beam must traverse through the detection space 20 from the primary beam opening 33 to the sample 41 -can be kept as small as possible. Scattering of the electron primary beam off gas molecules present in the detection space will be kept to a minimum in this embodiment.
• the quality of the detected signal can be improved by detecting other signals that are produced during irradiation of the sample and detection of the secondary electrons.
• Figure 8 depicts an embodiment that is analogous to the embodiment of Figure 6, except for the addition of a number of additional detection means. Parts with a functionality that is the same as the functionality of similar parts in Figure 6 are indicated using correspondingly similar reference numerals.
• the illustrated embodiment is a cross-section of an embodiment of a particle-optical device according to the current invention, which demonstrates a principally radial symmetry about the optical axis 40.
• the ion plate 36 which is embodied to capture excess gas ions that are generated because secondary electrons liberated from the sample 41 collide with gas molecules present in the detection space, is connected to an amplifier 45 that produces a signal at the output 46 that is proportional to the number of captured ions.
• the signal received at output 46 will generally be opposite in sign to the signal detected at output 39, because of the different polarity of the detected particles. If an image is produced on the basis of the signal received at output 46, then this will be a negative of the image produced on the basis of the signal generated by the detector combination 32, 38 and 39.
• FIG. 8 further depicts a sample holder 42, whereby the sample holder 42 forms, for example, a detection electrode. By connecting this detection electrode to an amplifier 47, one produces at the output 48 of the amplifier a signal that is proportional to the number of positive ions migrating to the sample 41.. In a manner similar to that described here above, the signal at this output can be used to improve the signal-to- noise ratio, or to improve the quality of the imaging.
• photon detector 49 which is connected to amplifier 50, producing at output 51 a signal that is proportional to the light intensity present in the detection space.
• photons may be generated that can be detected by 49.
• the number of detected photons i.e. the intensity of the detected light, is proportional to the number of collisions that have taken place between secondary electrons and gas molecules. Consequently, the detected light intensity is directly related to the secondary electron signal from the sample.
• Figure 8 further illustrates a data processing unit 55 that combines the signals from the outputs 39, 46, 48 and 51 of said detector combinations 32, 38, 39 and 36, 45, 46 and 42, 47, 48 and 49, 50, 51 , and, together with any other information obtained from the particle-optical device (not depicted), forms an image of the sample.
• This image can be displayed on display device 57, or can be sent to a computer 56, where it can be further processed.
• the sample mount 42 may be biased at a potential.
• a negative potential will enhance the strength of the magnetic Penning mechanism by increasing the field strength. It is also advantageous to apply a bias potential to the separation diaphragm 37 to achieve the same objective.

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• 2003
  • 2003-09-18 KR KR1020057004615A patent/KR101015116B1/ko not_active Expired - Lifetime
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  • 2003-09-18 EP EP03797915A patent/EP1540693A4/en not_active Withdrawn
  • 2003-09-18 JP JP2004538208A patent/JP4520303B2/ja not_active Expired - Lifetime
  • 2003-09-18 AU AU2003276900A patent/AU2003276900A1/en not_active Abandoned
  • 2003-09-18 US US10/664,796 patent/US6972412B2/en not_active Expired - Lifetime
  • 2003-09-18 AU AU2003275028A patent/AU2003275028A1/en not_active Abandoned
  • 2003-09-18 EP EP11172096.7A patent/EP2372743B1/en not_active Expired - Lifetime
  • 2003-09-18 JP JP2004538207A patent/JP4616938B2/ja not_active Expired - Lifetime
  • 2003-09-18 EP EP03759297.9A patent/EP1540692B1/en not_active Expired - Lifetime

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