Microchannel electron multipliers

Abstract

Microchannel plates (MCPs) and channel electron multipliers (CEMs) having channels etched by a directionally applied flux of reactive particles are disclosed. The channels are activated with thin film dynodes. Various embodiments including monolithic and stacked devices are disclosed. Activation of the channels is achieved by various techniques including CVD, LPD and native growth by oxidation.

Description

BACKGROUND OF THE INVENTION

The invention relates to electron multipliers. In particular, the invention relates to monolithic electron multipliers and microchannel plates (MCP) formed from an isotropic etchable material.

Conventional microchannel plate manufacture relies on the glass multifiber draw (GMD) process. Individual composite fibers, consisting of an etchable soluble barium borosilicate core glass and an alkali lead silicate cladding glass, are formed by drawdown of a rod-in-tube preform, packed together in a hexagonal array, and then redrawn into hexagonal multifiber bundles. These multifiber bundles are next stacked together and fused within a glass envelope to form a solid billet. The billet is then sliced, often at a small angle 8.degree.-15.degree. from the normal to the fiber axes. The resulting wafers are edged and polished into a thin plate. The soluble core glass is then removed by a suitable chemical etchant to produce a wafer containing an array of microscopic channels with channel densities of 10.sup.-5 -10.sup.7 /cm.sup.2. Further chemical treatments followed by a hydrogen reduction process produces a thin wafer of glass containing an array of hollow channels with continuous dynodes of reduced lead silicate glass (RLSG) having conductive and emissive surface properties required for electron multiplication. Metal electrodes are thereafter deposited on the faces of the wafer to complete the manufacture of a microchannel plate.

The GMD method of manufacture described, while satisfactory and economical, suffers from certain disadvantages. For example, the size of the individual channels is governed by at least two glass drawing steps in the manufacturing process. Variations in fiber diameter can cause channel diameter variation, resulting in differential signal gain, both within an MCP and from one MCP to another.

Another disadvantage of current technology concerns channel arrangement. Individual composite fibers are packed in a hexagonal array before redrawing a multifiber bundle. This local array is moderately regular, but variation of fiber size can cause some disorder, and fibers on the periphery of a drawn multifiber bundle are often disordered and dislodged. Further, when these multifibers are stacked and pressed to form a billet there are invariably disruptions in the channel array and distortions in channel cross-section at the boundaries between the multifibers. As a result of these and other processing steps, there is no long-range order in channel location, and channel geometry is not constant across the array.

The manufacture of microchannel plates according to the GMD process is also limited in the choice of materials available. The multifiber drawdown technique demands that the starting materials, namely the core and cladding, both be glasses with carefully chosen temperature-viscosity properties; the fused billet must have properties conducive to wafering and finishing; core material must be preferentially etched over the cladding with very high selectivity; the clad material must ultimately exhibit sufficient surface conductivity and secondary electron emission properties to function as a continuous dynode for electron multiplication. This set of constraints greatly limits the range of materials suitable for manufacturing MCPs with the present technology.

Multi-component alkali lead silicate and barium borosilicate glasses are typically used as the cladding and core materials, respectively, in manufacturing MCPs. To obtain satisfactory continuous dynode action with present materials, the ratio (.alpha.) of channel length (L) to channel diameter (D) is typically 40 or more. This aspect ratio is routinely achieved in conventional MCPs by virtue of the extremely high etch selectivity between core and cladding material. However, the difficulties of constructing such a substrate become more critical as the channel diameter and pitch (center to center spacing) of the channels is reduced to below 10 microns.

Attempts have been made to crystallize a photosensitive glass in a lithographically-defined pattern so as to render the crystallized regions selectively etchable from the glass leaving behind an array of channels for producing a microchannel plate. However, only moderate etch selectivity between the crystalline and glass phases yields through channels with non-parallel side walls and limits the minimum channel diameter to about 25 .mu.m. Moreover, the formation of a two-layer secondary emissive and conductive surface in the microchannels is accomplished by a number of cumbersome and difficult steps.

Attempts have also been made in selectively etching a silicon wafer sliced with a set of its crystalline (111) planes normal to the (110) faces of the slice. However, simple holes with vertical side walls extending through the wafer cannot be achieved due to well-known crystallographic constraints.

SUMMARY OF THE INVENTION

The present invention is designed to overcome the limitations and disadvantages of the described prior arrangements. In particular, and in accordance with a preferred embodiment of the invention, there is disclosed an electron multiplier in the form of a microchannel plate comprising a wafer of etchable material having been subjected to a directionally applied flux of reactive particles against at least one face of the wafer in selected areas corresponding to microchannel locations. The active species may be energetic and/or chemically active. The directionally applied flux species removes material from the selected areas exposed thereto to produce microchannels in the wafer oriented in accordance with the directionality of the applied flux.

In one embodiment of the invention the microchannels are etched through from one face of the wafer to the other or from both faces. In another embodiment of the invention the microchannels are etched to a selected depth within the wafer and material from the opposite face is ground or removed to a depth sufficient to expose the ends of the channel within the wafer.

In accordance with the invention, channel etching selectivity is achieved by applying an etch mask to at least one face of the wafer exposed to the flux. In one embodiment the etch mask may be a photosensitive polymer which has been processed to establish a pattern of microchannel locations. In another embodiment the mask may be a metallized etch resist or a chemically durable film deposited or grown on the wafer and then apertured photolithographically to define microchannel locations.

The channels may be activated to exhibit secondary emission and a current carrying capacity sufficient to replenish emitted electrons and to establish a field for accelerating the emitted electrons. The activation may be achieved by the various techniques including forming an active layer or a continuous dynode on the channel walls by chemical vapor deposition (CVD), liquid phase deposition (LPD) and native growth by reaction with a reactive species. Activation may also include doping the film with species to control surface conductivity and secondary electron emission.

In accordance with the present invention major transverse channel dimensions (e.g. diameters) less than about 4 .mu.m and having a pitch less than about 6 .mu.m are readily achieved. Thin films for channel activation range in thickness over about 2-1000 nm. In exemplary embodiments, a thin film for a continuous dynode on a dielectric substrate has a thickness of 300 nm, whereas a film for a semiconductor substrate has a thickness of 20 nm. Also, channel walls are virtually parallel as a result of the directionality of reactive particle etching.

Various materials may be used for the microchannel plate according to the present invention, including semiconductors such as GaAs, GaP, InP, AlAs, AlSb, Si, substantially single component dielectrics such as Si.sub.3 N.sub.4, AlN, Al.sub.2 O.sub.3, SiO.sub.2 glass, and R.sub.2,O-BaO-PbO-SiO.sub.2 glasses (where R is one or more of the following: Na, K, Rb, Cs). Other embodiments of the invention include process steps and resulting microchannel plate configurations which include channels of different shapes and sizes and channels with axes in parallel and intersecting planes and trenched channels.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a fragmentary perspective view of a microchannel plate in accordance with the present invention;

FIGS. 2A-2D illustrate in step wise fashion a preferred embodiment of the process according to the present invention;

FIGS. 3A-3D illustrate in step wise fashion an alternative embodiment of the process according to the present invention employing a chemically durable etching mask;

FIGS. 4 and 5 illustrate alternative embodiments of the process according to the present invention;

FIG. 6 is a fragmentary detail of a MCP according to the present invention with a semiconductive substrate;

FIG. 7 is a fragmentary detail of a MCP according to the present invention having a dielectric substrate etched in accordance with the teachings of the present invention and having a dynode produced by CVD processing;

FIG. 8 is a fragmentary detail of a MCP according to the present invention having an alkali lead silicate substrate having been etched in accordance with the teachings of the present invention; and

FIG. 9A-9F illustrate in fragmentary detail various embodiments of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT

An MCP 10 fabricated in accordance with the present invention is illustrated in FIG. 1. The MCP 10 may be in the form of a wafer 12 formed of a generally homogenous, etchable material. Such materials include semiconductive materials, including but not limited to GaAs, GaP, InP, AlAs, AlSb, Si, single component dielectrics such as Si.sub.3 N.sub.4, AlN, Al.sub.2 O.sub.3, SiO.sub.2 glass, and multicomponent dielectrics such as R.sub.2 O-BaO-PbO-SiO.sub.2, glasses (where R is one or more of the following: Na, K, Rb, C.sub.s). The wafer 12 is sliced in a manner which can be independent of the crystallographic planes of a crystalline wafer material.

In a preferred embodiment microchannels 14 are formed in the wafer 12 in an array as shown at a bias angle 16. Thin film dynode 15, formed of semiconductive and emissive layers for a thin film dynode on dielectric substrate; or emissive layer on semiconductive substrate, may be deposited or grown on the walls of the channels 14 by various methods such as set forth in the copending application of Tasker et al., Ser. No. 395,588 filed Aug. 18, 1989, and commonly assigned to the assignee herein. Conductive electrodes 18 and 20 are formed on the respective opposite faces 22 and 24 of the wafer as shown. In operation, a bias voltage (V.sub.B) and current (i.sub.B) is supplied across the electrodes 18 and 20 by a source 26 which is illustrated schematically.

The microchannels 14 are formed in the wafer 12 at the bias angle 16 by an anisotropic etching process which is illustrated schematically in FIGS. 2A-2D. In FIG. 2A, the wafer 12 may be prepared by various known techniques such as slicing it from a bulk homogeneous material (not shown) or by growing it and thereafter polishing and cleaning the surfaces 22 and 24. Such a material may be a single crystalline, polycrystalline or amorphous structure. In preparation for etching in FIG. 2B at least one face 22 of the wafer 12 is masked with a coating 28 which may be a photosensitive polymer material. The coating 28 is selectively exposed to light 30 through an apertured mask 32 to produce a pattern of exposed areas 34 on the coating 28 which correspond to the desired pattern of microchannels. The exposed areas 34 of the coating 28 may thereafter be removed by a developing procedure (FIG. 2B) thereby forming apertures 36 in the coating 28 (FIG. 2C) which expose selected portions of the surface 22 of the wafer 12. The masked wafer 12 is subjected to a directionally applied flux of reactive particles 38 (FIG. 2C) which attacks the substrate material comprising the wafer 12 through the apertures 36 in the coating 28 to thereby form the microchannels 14. The coating 28 is thereafter removed, the channels are activated, thereafter electrodes 18, 20 may be applied to the faces 22, 24 of the wafer 12 resulting in a microchannel plate 40 shown in FIG. 2D.

Alternatively, for certain substrates 12, e.g. silicon, the coating 28 forming the etch mask may be formed by an oxidation process or deposition process illustrated in FIGS. 3A-3D. In the arrangement illustrated, the wafer 12 is formed as noted and subjected or exposed to oxygen at elevated temperatures to produce a hard silicon oxide coating 13 illustrated in FIG. 3A. Thereafter the wafer 12 and silicon oxide coating 13 receive a coating of photopolymer 28 which is exposed through the photomask 32 by light 30 for producing exposed areas 34 (FIG. 3B) which are developed as noted above, thereby resulting in an etch mask 28 having apertures 36 therein (FIG. 3C). A first flux of reactive particles 38-1 is applied to the wafer 12 for producing apertures 15 in the oxide layer 13 as shown. Thereafter, the photomask 28 is removed and a second flux of reactive particles 38-2 is applied against the wafer through the apertured oxide mask 13 for producing the channels 14. The oxide mask 13 is more durable than photopolymer materials and thus allows for relatively deep channel formation in the substrate 12 as shown in FIG. 3D. Thereafter the apertured wafer 12 may be electroded. The etching fluxes 38-1 and 38-2 may be the same or different particles operating under various conditions as necessary. For example, a relatively high intensity flux 38-1 may be applied to make the apertures 15 in the silicon oxide film 13 while a flux of a different energy 38-2 may be applied for producing the channels 14. It is also possible that the polymer coating 28 may serve as a mask for chemical wet etch or dry etch step whereby the apertures 15 are formed in the silicon oxide layer 13. Alternatively, an etch mask may be formed of some other chemically durable material, for example, Si.sub.3 N.sub.4 or Al.sub.2 O.sub.3 by native growth, CVD, LPD or other method as desired.

If desired, and as shown in FIG. 4, an etch resistant metal coating 28 of W, Ni or Cr may be applied to either or both sides 22,24 of the wafer 12 by sputtering evaporation or other method. The coating 28 may be subjected to photolithographic processes and subsequent development to produce apertures 36 and may thus serve as a durable mask for the wafer 12 during the channel 14 etching step with applied flux of particles 38 (FIG. 2C). If desired, such a coating may serve as an electrode for the MCP 44.

Etching may be accomplished by a direction-specific ion beam and/or glow discharge. The ion beam may be produced as set forth in the publication entitled "Large Area Ion Beam Assisted Etching of GaAs with High Etch Rates and Controlled Anisotrophy", Lincoln et al., J. Vac. Sci. Technol B., Vol. 1, No. 4, Oct-Dec. 1983. Etching may also employ various reactive species. The particular species is selected taking into account the type of etching process and the substrate to be etched.

It should be understood that the microchannels 14 may be etched in accordance with the teachings of the present invention for a time sufficient to establish the channels from one face 22 of the wafer 12 to the opposite face 24 as shown in FIG. 2C. It is also possible to etch straight through channels 14 from both sides 22,24 of the wafer as illustrated in FIG. 4; or it is possible to etch chevron, and one-to-many channels by two-faced etching hereinafter described.

It is also within the teachings of the present invention to terminate the etching step at a given depth 42 as more clearly illustrated in FIG. 5. Excess material 46 beyond the terminal ends 48 of the channels 14 within the wafer 12 may be removed by grinding, polishing, wet isotropic etch, plasma etch or by ion milling.

According to an embodiment of the present invention, in the MCP 110 shown in FIG. 6, the wafer 112 may be made of a bulk semiconductor for carrying current i.sub.B. The channels 114 formed therein have an emissive 115 layer formed therein. In the case of a semiconductor wafer 112, improved electron multiplication behavior and reduction of ion feedback may be achieved. The electric field normal to the wafer midplane 128 and inclined with an angle 134 with respect to the channel axis Ac allows multiplication of electrons but reduces ion feedback noise preventing energetic positive ions I from impacting the channel wall near the input face of the MCP 110.

In another embodiment, a single component dielectric substrate -12 such as silica glass as shown in FIG. 7 may be etched in accordance with the teachings of the present invention to produce microchannels 114 therein. Thereafter a current carrying, semiconductive coating 152 may be first deposited on the channel walls as shown and emissive coating 154 may be deposited or grown over the current carrying layer 152. As used herein a single component dielectric is a material which is substantially a single component and conventional adjuvants. Deposition of the coatings 152 and 154 may be by various chemical vapor deposition (CVD) techniques typically at reduced pressure and at elevated temperatures to thereby produce the continuous dynode 150 or by other techniques.

Alternatively, as shown in FIG. 8, the substrate 112 may be a multicomponent dielectric material such as alkali lead silicate glass which has been anisotropically etched in accordance with the teachings of the present invention to produce microchannels 114 therein. Thereafter, the etched substrate 112 may be first subjected to a wet-etch with a weak acid to deplete the lead from the glass adjacent the channel walls 114 and then be hydrogen reduced in order to produce a continuous dynode 140 with a semiconductive layer 165 in the substrate 112 and an emissive surface 164 as shown.

Other variations of the present invention are also possible. For example, it may be possible to perform the etching step through the substrate from both sides at the same bias angle and at the same time or sequentially in order to produce straight microchannels in the configuration illustrated in FIG. 4. It may also be possible to perform the etching step from each side at different bias angles in order to produce microchannels 172 entering the plate 170 at a first bias angle 174A and leaving the plate at a second bias angle 174B in a monolithic structure (FIG. 9A). It is also possible to produce a microchannel plate 180 having individual channels 182-1, 182-2 which are of various sizes (FIG. 9B). For example, small and large channels may be arranged in a pattern or matrix. It is further possible to produce a MCP 190 with an arrangement of microchannels such that a single relatively large channel 192-1 is interconnected with one or more relatively smaller channels 192-2 in a monolithic structure (FIG. 9C). It is also possible to form an electron multiplier having one or more elongated trenches 204 in a single substrate 202 or alternatively in a stack of such substrates together in side-by-side configuration to form a laminated microchannel structure 200 (FIG. 9D). It is also possible to form an electron multiplier 220 with branched trenches 224 in which the input end 224-I is a single trench and the output has branched channels 224-0 each of which forms a separate and distinct output which may be individually read or controlled (FIG. 9E). In yet another embodiment of the invention it may be possible to form a wafer 130 having trenched channels 134-1 . . . 134-2 in opposite sides 131-1 and 131-2 formed in which the trenched channels 134-1 . . . 134-2 are oriented so that they are related to the other cross-wise in order to form a pseudo channel matrix (FIG. 9F).

Further, processing of the channels which are formable in accordance with the present invention may be staged so that the coatings or the dynode surfaces exhibit different characteristics. For example, it is possible to form a channel in a plate by etching to a selected depth in the substrate and thereafter applying conductive and emissive films. In subsequent etching steps the channel may be formed to an increased depth within the wafer and additional coatings may be applied such that the conductivity or emissivity of the dynode thus produced varies lengthwise of the channel and in a stepwise or graded fashion. Alternatively, each branch of a channel may be individually treated after it is formed in order to provide a branched channel arrangement with different electron multiplication properties at each output.

In accordance with the present invention, because the substrate may be anisotropically etched in order to produce an apertured microchannel plate, a number of the processing steps associated microchannel plate manufacture by the GMD process are eliminated. Accordingly, some of the constraints in the properties of suitable substrate materials are significantly relaxed thereby allowing greater latitude in substrate materials selected. In addition, the materials properties necessary for the manufacture of microchannel plate substrates may be divorced or decoupled from the materials properties necessary for the production of continuous dynodes.

As a direct result of the present invention, smaller channel diameters, or widths less than about 4 .mu.m and pitch, less than about 6 .mu.m may be achieved thereby resulting in improved spatial and temporal characteristics (e.g. resolution and speed). The channel and pitch dimensions are better than can be achieved with the conventional GMD processes or methods employing photosensitive glass. Exemplary film thicknesses are about 2-20 nm for electron-emissive films and about 10-1000 nm for current-carrying films and are achievable with CVD, LPD and growth by reactive techniques such as set forth in Tasker et al., Ser. No. 395,588 filed Aug. 18, 1989, the teachings of which are incorporated herein by reference. Other significant advantages of the invention include the ability to fabricate periodic arrays for advanced address/readout schemes and areal arrays of microchannels with relatively large linear dimensions. Reduction or elimination of fixed pattern defects caused by variation of channel diameter is also achieved. The ability to select substrate materials based upon physical properties other than formability allows greater design flexibility. For example, higher operating temperatures may be achieved by use of refractory substrates. A thermally conductive substrate allows more efficient dissipation of Joule heat and thus may lead to greater thermal stability. Improved noise characteristics and dynamic range by use of high-purity substrate materials also results.

While the invention has been described in connection with specific embodiments thereof, it will be understood that it is capable of further modifications. This application is intended to cover any variations, uses or adaptations of the invention following, in general, the principles of the invention, and including such departures from the present disclosure as come within known and customary practice within the art to which the invention pertains.

Claims

1. A microchannel plate comprising a monolithic body in the form of a wafer of etchable material having opposite faces and a plurality of uniform microchannels extending through the wafer from one face to the other, the microchannels with wall surface portions being formed in the wafer by a selectively applied direction specific flux of reactive particles directed against at least one face of the wafer for anisotropically etching the microchannels therein, said microchannels having a major transverse dimension on the order of <10 .mu.m, being closely spaced on the order of <2 .mu.m in pitch and having substantially straight, parallel wall portions for receiving a thin film of thickness on the order of about 10 nm-1000 nm said dimension, pitch and thickness being selected so as to result in an operative device; and

a continuous thin film dynode to provide electron multiplication formed on the wall portions of the microchannels, said dynode formed by at least one of low pressure chemical vapor deposition, liquid phase deposition and by native growth of a film by an oxidizing reaction with a reactive species above ambient temperature.

2. The microchannel plate of claim 1 wherein the microchannels are formed through the body from one side to another.

3. The microchannel plate of claim 1 wherein the microchannels are formed in the body a selected distance from one of said faces to closed end portions within the body and a portion of the body beyond the closed end portions is thereafter removed to form the other opposite face and to expose and open said closed end portions so that the microchannels extend through the wafer.

4. The microchannel plate of claim 3 wherein the portion of the body is removed by grinding.

5. The microchannel plate of claim 3 wherein the portion of the body is removed by chemical etching.

6. The microchannel plate of claim 3 wherein the portion of the body is removed by plasma etching or ion milling.

7. The microchannel plate of claim 1 wherein the body is a semiconductive material.

8. The microchannel plate of claim 7 wherein the semiconductive material is selected from the group consisting of GaAs, GaP, InP, AlAs, AlSb and Si.

9. The microchannel plate of claim 1 wherein the body is a single component dielectric material.

10. The microchannel plate of claim 9 wherein the dielectric is selected from the group consisting of: Si.sub.3 N.sub.4, AlN, Al.sub.2 O.sub.3, SiO.sub.2 glass.

11. The microchannel plate of claim 1 wherein the flux of reactive particles is produced by an ion beam.

12. The microchannel plate of claim 1 wherein the flux of reactive particles is produced by a glow discharge.

13. The microchannel plate of claim 1 wherein the flux of reactive particles is a plasma assisted ion beam.

14. The microchannel plate of claim 1 wherein the flux is an ion assisted beam.

15. An electron multiplier comprising at least one monolithic body of etchable material having at least one channel with wall portions formed therein by a selectively applied flux of direction specific reactive particles directed against the body for anisotropically etching at least one channel in the body, said channel having wall portions for receiving a thin film of thickness on the order of about 2 nm-1000 nm; and

a continuous thin film dynode to provide electron multiplication formed on the wall portions of the channel, said dynode formed by at least one of low pressure chemical vapor deposition, liquid phase deposition and by native growth of a film by an oxidizing reaction with a reactive species above ambient temperature.

16. The electron multiplier of claim 15 wherein the body is a substrate having opposite faces and said at least one channel is formed therein by application of the flux of reactive particles against opposite faces of the substrate.

17. The electron multiplier of claim 16 wherein the application of the flux of reactive particles occurs at a selected bias angle for each face of the substrate.

18. The electron multiplier of claim 15 wherein the body has a plurality of channels of differing cross section but with uniform dimensions within a given cross section.

19. The electron multiplier of claim 15 wherein the body of etchable material is in the form of a wafer having opposite planar faces and a plurality of channels formed in the wafer in groups, a first group of said channels is formed therein by the selectively applied flux of reactive particles directed against one face of the wafer and of a second group of said channels is formed in registration and communication with selected ones of the channels in the first group from the opposite face of the wafer.

20. The electron multiplier of claim 19 wherein each channel of said first group of channels is in registration with a selected plurality of the channels in said second group of channels.

21. The electron multiplier of claim 15 wherein a first body is in the form of a wafer having opposite planar faces and said at least one channel is in the form of at least one elongated trench formed in the wafer and having an open side which is enclosed by a planar face of a second body.

22. The electron multiplier of claim 15 wherein the body is a substrate having opposite faces and end wall portions and said at least one channel is in the form of an elongated trench extending through the substrate from one end wall to the other.

23. The electron multiplier of claim 15 wherein the body is in the form of a wafer having opposite planar faces and a plurality of channels in the form of two orthogonal arrays of trenched channels are etched in the wafer from opposing faces thereof and meet within the body is form apertures therein.

24. The electron multiplier of claim 21 wherein said at least one trench is in the form of an elongated continuous interconnected branched trench in the body.

25. The electron multiplier of claim 15 wherein the etchable material is selected from the group consisting essentially of elemental and binary semiconductors and single component dielectrics.

26. The microchannel plate of claim 1 wherein the microchannels are formed in the wafer by application of the flux of reactive particles at a selected angle against at least one face thereof.

27. The electron multiplier of claim 18 wherein the channels of differing cross section are disposed in an array at a selected spacing.

28. The electron multiplier of claim 21 wherein a plurality of wafers are stacked atop one another.

29. A monolithic microchannel plate comprising a body of etchable material in the form of a wafer having opposite faces and interconnected microchannel portions having straight walls and being registrably formed in each face of the wafer by a corresponding selectively applied direction specific flux of reactive particles directed against opposite faces of the wafer for anisotropically etching the microchannel portions into the wafer until said microchannel portions connected there within to form continuous microchannels, said microchannels having walls for receiving a thin film of a thickness not more than 1000 nm; and continuous thin film dynodes formed on the walls of the microchannels.

30. The electron multiplier of claim 29 wherein the microchannel portions extending into each face of the wafer lie at selected angles so as to form microchannels which change direction at an oblique angle within the wafer.

31. The electron multiplier of claim 29 wherein the microchannel portions in each face of the body are formed simultaneously.

32. A microchannel plate comprising a body in the form of a wafer of etchable material having opposite faces and a plurality of uniform microchannels extending through the wafer from one face to the other, the microchannels with wall surface portions being formed in the wafer by a selectively applied direction specific flux of reactive particles directed against at least one face of the wafer for anisotropically etching the microchannels therein, said microchannels having a major transverse dimension of less than 4 .mu.m and being closely spaced with a pitch of less than 6 .mu.m and having substantially straight, parallel wall portions for receiving a thin film of thickness of about 2 nm-1000 nm said dimension, pitch and thickness being selected so as to result in an operative device; and

a continuous thin film dynode to provide electron multiplication formed on the wall portions of the microchannels.

33. The microchannel plate of claim 32 wherein the body is a dielectric material and the thin film thickness is about 300 nm.

34. The microchannel plate of claim 32 wherein the body is a semiconductor material and the thin film thickness if about 20 nm.

35. An electron multiplier comprising a body of etchable material having at least one channel with wall portions formed therein by a selectively applied flux of direction specific reactive particles directed against the body for anisotropically etching said at least one channel in the body, said channel having wall portions for receiving a thin film of thickness not more than 1000 nm; and

a continuous thin film dynode to provide electron multiplication formed on the wall portions of the channel.

36. The electron multiplier of claim 35 wherein the body is a dielectric material and the thin film thickness is about 300 nm.

37. The electron multiplier of claim 35 wherein the body is a semiconductor material and the thin film thickness is about 20 nm.