Method for forming microscopic 3D structures
First Claim
1. A method for forming a structure on a substrate, the method comprising:
- providing a substrate, said substrate showing a surface on which the structure is built;
repeatedly performing the steps of;
a) adding a thin layer of a fluid precursor material with a predetermined thickness on the surface, the fluid precursor material forming a solid or liquid layer on the surface, the layer defining a new surface;
b) converting part, but not all, of the precursor material to another material or to another physical state by irradiating part of the layer with particles, while the unconverted part of the precursor material stays unconverted on the surface;
the repeatedly performed steps of a) and b) followed by;
c) the removal of part, but not all, of the precursor material;
the penetration depth of the particles sufficient to convert the precursor material over the complete thickness of one layer, the penetration depth of the particles insufficient to convert the precursor material that, immediately prior to step c), is closest to the substrate,as a result of which a structure is built in which, prior to step c), unconverted precursor material is sandwiched between the substrate and converted precursor material,wherein;
steps a) and b) are performed in a vacuum, andthe thin layer is formed by directing a jet of fluid to the substrate.
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Abstract
A method for forming microscopic 3D structures. In the method according to the invention a substrate (105) is placed in a Scanning Electron Microscope (SEM). The SEM is equipped with a Gas Injection System (GIS) (110) for directing a jet of precursor fluid to the substrate. The substrate is cooled below the freezing point of the precursor gas so that a frozen layer of the precursor gas can be applied to the substrate. By now repeatedly applying a frozen layer of the precursor to the substrate and irradiate the frozen layer with an electron beam (102), a stack of frozen layers (130) is built, each layer showing an irradiated part (131) in which the precursor is converted to another material. After applying the last layer the temperature is raised so that the unprocessed precursor (132) can evaporate. As a result 3D structures with overhanging features can be built.
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Citations
23 Claims
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1. A method for forming a structure on a substrate, the method comprising:
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providing a substrate, said substrate showing a surface on which the structure is built; repeatedly performing the steps of; a) adding a thin layer of a fluid precursor material with a predetermined thickness on the surface, the fluid precursor material forming a solid or liquid layer on the surface, the layer defining a new surface; b) converting part, but not all, of the precursor material to another material or to another physical state by irradiating part of the layer with particles, while the unconverted part of the precursor material stays unconverted on the surface; the repeatedly performed steps of a) and b) followed by; c) the removal of part, but not all, of the precursor material; the penetration depth of the particles sufficient to convert the precursor material over the complete thickness of one layer, the penetration depth of the particles insufficient to convert the precursor material that, immediately prior to step c), is closest to the substrate, as a result of which a structure is built in which, prior to step c), unconverted precursor material is sandwiched between the substrate and converted precursor material, wherein; steps a) and b) are performed in a vacuum, and the thin layer is formed by directing a jet of fluid to the substrate. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14)
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15. A method for forming a structure on a substrate, the method comprising;
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placing the substrate in a vacuum chamber; forming a structure by; (a) directing a jet of precursor fluid at the surface of the substrate to form solid or liquid layer of precursor material having a predetermined thickness on the surface, the precursor material reacting in the presence of the particle beam to form a desired solid material that is used to form a structure on the substrate; (b) irradiating a part, but not all, of the precursor material layer with a particle beam, the irradiated part of the precursor material converting in the presence of the particle beam into the desired solid material, the particle beam having sufficient energy to cause the reaction of precursor material for the complete predetermined thickness of the layer, and not irradiating the remaining part of the precursor material layer with the particle beam; (c) directing a jet of precursor fluid at the surface of the substrate to form an additional solid or liquid layer of precursor material having a predetermined thickness on the surface, said additional layer formed on top of the irradiated and non-irradiated parts of the previous layer; (d) irradiating a part, but not all, of the additional precursor material layer with a particle beam, the precursor material converting in the presence of the particle beam into the desired solid material, the particle beam having sufficient energy to cause the reaction of precursor material for the complete predetermined thickness of the additional layer, but the penetration depth of the particle beam being insufficient to convert non-irradiated precursor material in the previous layer, and not irradiating the remaining part of the additional precursor material layer with the particle beam; (e) repeating steps (a) through (d) until the desired structure has been formed; and removing the non-irradiated precursor material from the substrate surface to leave the desired structure of solid material on the substrate. - View Dependent Claims (16, 17, 18, 19, 20, 21, 22, 23)
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Specification