Specific Process Knowledge/Thin film deposition/DiamondCVD/Diamond CVD process details: Difference between revisions

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=Diamond growth by MPCVD at Nanolab=
=Diamond growth by MPCVD at Nanolab=
At Nanolab, it is possible to grow single- and polycrystalline diamond in the [[Specific Process Knowledge/Thin film deposition/DiamondCVD|SEKI diamond CVD]]. The diamond CVD applies a microwave plasma to a mix of H2, CH4 and O2 gas to create a reactive mix that allows diamond to grow from an existing diamond lattice.
At Nanolab, it is possible to grow single- and polycrystalline diamond in the [[Specific Process Knowledge/Thin film deposition/DiamondCVD|SEKI diamond CVD]]. The diamond CVD applies microwaves to create plasma in a mix of H2, CH4 and O2 gas. This reactive mix allows diamond to grow from an existing diamond lattice.


==Diamond formation==
==Diamond formation==
[[File:diamond growth.png|upright=3|alt=Structural formula diagrams of the growing diamond lattice showing how a hydrogen radical knocks off a hydrogen atom that terminates the diamond lattice, then a methane radical attaches to the activated site. The same thing happens at an adjacent site and finally one hydrogen radical after another knock off two hydrogen atoms on the recently-attached methane sites to create a new single carbon-carbon bond. The two new carbon atoms are also still bound to two hydrogen atoms each.|right|thumb|Structural formula diagrams of diamond growth]]
Diamond is grown by depositing carbon from the CH<sub>4</sub> on a substrate. If the carbon forms an sp3 bond to other carbon atoms, diamond is grown. Otherwise it will be etched away by a high concentration of H<sub>2</sub>. Diamond is very inert, but the plasma in the CVD equipment creates hydrogen radicals that in turn create active sites on the diamond surface. These active sites react with methane radicals that are also created in the plasma. In practice oxygen is also introduced to the chamber and helps the diamond grow.


Diamond is grown by depositing carbon from the CH<sub>4</sub> on a substrate. If the carbon forms an sp3 bond to other carbon atoms, diamond is grown. Otherwise it will be etched away by a high concentration of H<sub>2</sub>. Diamond is very inert, but the plasma in the CVD equipment creates hydrogen radicals that in turn create active sites on the diamond surface. These active sites react with methane radicals that are also created in the plasma.  
In order to obtain diamond bonds the temperature has to be sufficiently high. If the temperature is too low the carbon will fond sp2 bonds and will result in so-called "diamond-like carbon".  


The figure on the right is meant to illustrate the process with the generation of radicals and diamond bonds. In practice the process is more complicated, as oxygen is also introduced to the chamber and helps the diamond grow.
In order to obtain diamond bonds the temperature has to be sufficiently high. If the temperature is too low the carbon will fond sp2 bonds and will result in so-called "diamond-like carbon".
[[File:diamond bonds.png|upright=1.5|alt=3D-image of the Diamond crystal lattice. Each carbon atom is bound to the four nearest carbon atoms via sp3 hybridization. On the left you see an extended diamond lattice. On the right you see a carbon atom with four sp3 hybrid orbital lobes extending from the center with an angle of 109.5 degrees between the lobes. |left |thumb|Diamond bonding]]
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== Poly- and single crystalline diamond ==
== Poly- and single crystalline diamond ==
[[File:diamond example.png|upright=2.5|alt=Two-inch wafer that has a speckled dark gray appearance with three small transparent partly overlapping squares in one area on top. The wafer is labeled as "polycrystalline diamond substrate" and the squares are labeled as "single crystal diamond" |right|thumb|Single- and polycrystalline diamond]]
[[File:diamond example.png|upright=2.5|alt=Two-inch wafer that has a speckled dark gray appearance with three small transparent partly overlapping squares in one area on top. The wafer is labeled as "polycrystalline diamond substrate" and the squares are labeled as "single crystal diamond." |right|thumb|Single- and polycrystalline diamond. Photo by Kristian Hagstedt, DTU Nanolab.]]


===Polycrystalline diamond===
===Polycrystalline diamond===


For polycrystalline growth the substrate must be seeded with diamonds. This is commonly done by sonicating the substrate in a solution of water with nano diamonds, although other solvents may give better results ([https://www.sciencedirect.com/science/article/pii/0925963596005468|see this paper]). After sonication the substrate is rinsed and blow-dried.
For polycrystalline growth the substrate must be seeded with diamonds. This is commonly done by sonicating the substrate in a solution of water with nano diamonds, although other solvents may give better results ([https://doi.org/10.1016/j.diamond.2003.11.073 see this paper]). After sonication the substrate is rinsed and blow-dried.


Note that the substrate must be able to withstand high temperature (at least 700°C) and also high temperature gradients, as the center of the substrate is heated more than the edges. In practice this means that to grow diamond on Si it is necessary to use a thick Si substrate (see image of a thick poly-Si sample on the right). Ordinary 500 micron thick 2" wafers break due to stress induced by the temperature gradient.  
Note that the substrate must be able to withstand high temperature (at least 700°C) and also high temperature gradients, as the center of the substrate is heated more than the edges. In practice this means that to grow diamond on Si it is necessary to use a thick Si substrate (see image of a thick poly-Si sample on the right). Ordinary 500 micron thick 2" wafers break due to stress induced by the temperature gradient.  
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Polishing is needed after deposition if the polycrystalline diamond layer has to be smooth. This cannot be done here at Nanolab, so the film must be sent away for polishing. Following polishing it is possible to etch the film in the metal ICP, but etching cannot take the place of polishing as different crystal faces of the diamond etch at different rates.
Polishing is needed after deposition if the polycrystalline diamond layer has to be smooth. This cannot be done here at Nanolab, so the film must be sent away for polishing. Following polishing it is possible to etch the film in the metal ICP, but etching cannot take the place of polishing as different crystal faces of the diamond etch at different rates.


Thinning is needed if the diamond layer has to be very thin as a uniform diamond layer can only be deposited above 1 μm thickness.
Thinning is needed if the diamond layer has to be very thin because a uniform diamond layer can only be deposited above 1 μm thickness.


===Single crystal diamond===
===Single crystal diamond===
It is possible to grow very clean diamond in the SEKI system which should be usable for thermal and perhaps optical applications. To grow single crystal diamond we must use a single crystalline diamond substrate (these are purchased and typical dimensions might be 2x2 mm with 0.1 mm thickness, see image on the right). We have not investigated whether it is possible to distinguish the transition from the purchased substrate to the newly grown layer.
It is possible to grow very clean diamond in the SEKI system which should be usable for thermal and perhaps optical applications. To grow single crystal diamond we must use a single crystalline diamond substrate (these are purchased and typical dimensions might be 2x2 mm with 0.1 mm thickness, see photo). We have not investigated whether it is possible to distinguish the transition from the purchased substrate to the newly grown layer.


We cannot grow diamond for quantum applications here at Nanolab as we cannot control the N<sub>2</sub> dopant level and dopant depth. This would require that we have our own hydrogen generator or that we buy (very expensive) extra pure bottled hydrogen. To control doping levels it is necessary to use 7N hydrogen and to mix it with a very small additional flow of hydrogen which again is mixed with only a few percent nitrogen. The hydrogen we have for general processing at Nanolab contains too much nitrogen. Nitrogen doping affects the optical and electronic properties of the diamond. For instance this can be used in magnetic sensors, which is a topic of research at DTU Physics.
We cannot grow diamond for quantum applications here at Nanolab as we cannot control the N<sub>2</sub> dopant level and dopant depth. This would require that we have our own hydrogen generator or that we buy (very expensive) extra pure bottled hydrogen. To control doping levels it is necessary to use 7N hydrogen and to mix it with a very small additional flow of hydrogen which again is mixed with only a few percent nitrogen. The hydrogen we have for general processing at Nanolab contains too much nitrogen. Nitrogen doping affects the optical and electronic properties of the diamond. For instance this can be used in magnetic sensors, which is a topic of research at DTU Physics.


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Latest revision as of 13:31, 13 June 2023

Feedback to this page: click here

All contents by DTU Nanolab staff unless otherwise noted.

Diamond growth by MPCVD at Nanolab

At Nanolab, it is possible to grow single- and polycrystalline diamond in the SEKI diamond CVD. The diamond CVD applies microwaves to create plasma in a mix of H2, CH4 and O2 gas. This reactive mix allows diamond to grow from an existing diamond lattice.

Diamond formation

Diamond is grown by depositing carbon from the CH4 on a substrate. If the carbon forms an sp3 bond to other carbon atoms, diamond is grown. Otherwise it will be etched away by a high concentration of H2. Diamond is very inert, but the plasma in the CVD equipment creates hydrogen radicals that in turn create active sites on the diamond surface. These active sites react with methane radicals that are also created in the plasma. In practice oxygen is also introduced to the chamber and helps the diamond grow.

In order to obtain diamond bonds the temperature has to be sufficiently high. If the temperature is too low the carbon will fond sp2 bonds and will result in so-called "diamond-like carbon".

Poly- and single crystalline diamond

Two-inch wafer that has a speckled dark gray appearance with three small transparent partly overlapping squares in one area on top. The wafer is labeled as "polycrystalline diamond substrate" and the squares are labeled as "single crystal diamond."
Single- and polycrystalline diamond. Photo by Kristian Hagstedt, DTU Nanolab.

Polycrystalline diamond

For polycrystalline growth the substrate must be seeded with diamonds. This is commonly done by sonicating the substrate in a solution of water with nano diamonds, although other solvents may give better results (see this paper). After sonication the substrate is rinsed and blow-dried.

Note that the substrate must be able to withstand high temperature (at least 700°C) and also high temperature gradients, as the center of the substrate is heated more than the edges. In practice this means that to grow diamond on Si it is necessary to use a thick Si substrate (see image of a thick poly-Si sample on the right). Ordinary 500 micron thick 2" wafers break due to stress induced by the temperature gradient.

Polishing is needed after deposition if the polycrystalline diamond layer has to be smooth. This cannot be done here at Nanolab, so the film must be sent away for polishing. Following polishing it is possible to etch the film in the metal ICP, but etching cannot take the place of polishing as different crystal faces of the diamond etch at different rates.

Thinning is needed if the diamond layer has to be very thin because a uniform diamond layer can only be deposited above 1 μm thickness.

Single crystal diamond

It is possible to grow very clean diamond in the SEKI system which should be usable for thermal and perhaps optical applications. To grow single crystal diamond we must use a single crystalline diamond substrate (these are purchased and typical dimensions might be 2x2 mm with 0.1 mm thickness, see photo). We have not investigated whether it is possible to distinguish the transition from the purchased substrate to the newly grown layer.

We cannot grow diamond for quantum applications here at Nanolab as we cannot control the N2 dopant level and dopant depth. This would require that we have our own hydrogen generator or that we buy (very expensive) extra pure bottled hydrogen. To control doping levels it is necessary to use 7N hydrogen and to mix it with a very small additional flow of hydrogen which again is mixed with only a few percent nitrogen. The hydrogen we have for general processing at Nanolab contains too much nitrogen. Nitrogen doping affects the optical and electronic properties of the diamond. For instance this can be used in magnetic sensors, which is a topic of research at DTU Physics.


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