Magnet Formation by the Surface Modification of Diamond with Manganese Detected by the Magnetic Flux Density on the Surface

A surface modification of diamond with manganese powder was attempted to make a magnetic functional surface for handling diamond. Manganese carbide, Mn7C3, was formed on diamond (110) by near-infrared radiation heating, resulting in a layered material with suppressing formation of Mn5C2. Investigated by a Hall-effect sensor, the magnetic flux density on the modified diamond surface showed ferromagnetic properties.


Introduction
Diamond has excellent properties of hardness, compressive strength, electric insulation, and chemical stability [1].Surface modification of diamond is an effective method to improve its wettability toward metals for industrial use [2].
Fine-grain diamond has been used as an abrasive powder for materials, however, they were not easily placed into particular areas to serve as blades.If diamond surface could be modified to have magnetic properties, we could evaluate the potential for the surface serve as a magnetic sensor and the damage of diamond.
We previously reported that manganese powder reacts with carbon atoms on diamond, forming manganese carbides and manganese oxides.The reaction only modified diamond (110) plane, providing ferrimagnetism at room temperature and the formation of layered manganese carbides [3].Karen et al. [4] characterized the magnetic properties of Mn 5 C 2 and Mn 7 C 3 bulk manganese carbides as paramagnetic.We believe that the modification of manganese powder along the Zhang et al. [6] reported six electromagnets set in a regular hexagonal apex construction, where the top surface of the cylinder exhibited magnetic levitation using a Hall-effect sensor.We attempted to detect the magnetic flux from 6 manganese carbide products set in hexagonal apexes on the diamond (110) surface by Hall-effect sensor.

Preparation of Diamond (110)
Single crystal diamond was processed by machining with an abrasive diamond grain and cleaning with acetone.The exposed face of diamond sample was (110) plane.Surface modification was processed as following: sputtering of gold coating (99.9% purity) by an argon ion beam on the diamond was conducted to prevent the reaction with manganese by smoothing a gold film of 60 nm in thickness.At six specific spots, as shown in Figure 1, the gold film was peeled off the diamond (110) surface under an optical microscope.Manganese powder with an average diameter of less 100 μm ground by ceramic ball milling to have a diameter less than 45 μm.
A bulk sample of diamond (natural type Ia, dimensions: 1.4 × 5.0 × 2.0 mm) was placed in a platinum cell, and a small amount of manganese powder was mounted on diamond (110).The specimens were irradiated with near-infrared radiation using an elliptic mirror with a quartz viewing port, as shown in Figure 2. The spot diameter was 18 mm, and it was focused on the manganese powder.
Diamond is transparent to near-infrared radiation, so the input heat was restricted to the surface of the diamond-mounted manganese powder.An ultra-  X-ray diffraction analysis was performed on the modified diamond surface to detect the carbide reaction products.

Magnetic Flux Measurements
Magnetic flux measurement was performed on the modified diamond surface and non-modified diamond surface to assess spontaneous magnetization using a Hall-effect sensor at room temperature and low temperature.The specifications of the Hall-effect sensor specification are listed in Table 1.The sensor was applied with 1.78 V and 250 mA, as shown in the measurement circuit.The output signal from the sensor was amplified by a thousand times.

Modified Diamond (110) by Manganese
The modified diamond (110) specimen is shown in Figure 3.It became black in color after modification, and hexagonal formations were observed.The spots are numbered clock wise from 1 to 6.The hexagons with metallic luster were observed.This reveals that the manganese powder directly contacted with diamond was different from the one contacted with the gold film.The X-ray diffraction pattern of the modified diamond (110) is shown in Figure 4.The peak of diamond (110) at 75˚ is observed.The peaks of pure manganese at 42.9˚ and 48˚ are observed, and pure gold peaks at 39˚ and 65˚ are also observed.Peaks of manganese carbides, Mn 5 C 2 at 44.8˚, 45.4˚ and 49.7˚are observed.These peaks Table 1.Specifications of the Hall-effect sensor.are overlapped with gold-manganese peaks.Peaks of Mn 7 C 3 at 39.5˚, 42.5˚ and 44.6˚ are observed.A peak of manganese oxide cannot be observed.

Detection of the Center by a Hall-Effect Sensor
In addition, using the active area of the Hall-effect sensor (1.02 mm in diameter), measurements of the magnetic flux densities on the hexagonal spots numbered from 1 to 6 were conducted at a low temperature of 262 K.The results of the measurements at 262 K are presented in Table 2.The amount of formed manganese carbide was different in each spots, and therefore, the measurement values were also different.The direction of the spontaneous magnetism was aligned.The temperature of 262 K was detected by the thermocouple on the chilled copper foil dipped into liquid nitrogen on the other side.
Since diamond was covered with gold, the modified diamond was moved on top of the Hall device, which was near the manganese carbide for the Hall sensor measurement.The magnetic flux densities were measured along diagonal lines.
The maximum magnetic flux density was measured near the center of the hexagonal spots, near spot 3. The measured magnetic flux density was 73 μT.

Discussion
In our previous study, diamond (110) modified by manganese provided ferromagnetic properties as shown in Figure 6, which shows the relationship between the magnetic flux density and the magnetic field at room temperature measured  by a vibration sample magnetometer (VSM).The magnetic moment 4 μemu (mA•m −1 ) was smaller than those of the 6 spots in this work because the bottom surface was also modified with manganese and weaken the magnetic moment of the top surface.The magnetic moment originating from the sectional spots without gold coating became large due to the small amount of manganese carbides.In this study, the modified diamond surface processed spontaneous magnetism, forming layered manganese carbides.For the magnetized layer, the magnetic flux density was greater than that at lower temperature.Surveying with the Hall-effect sensor along diagonal lines of the hexagon spots revealed the center of a hexagon on diamond (110).This indicates that diamond modified with manganese can be precisely controlled by magnetic force.

Conclusion
A diamond surface was modified with a manganese powder using near-infrared heating at 623 K.The X-ray diffraction pattern showed the formation of manganese carbides of Mn 7 C 3 and Mn 5 C 2 .The diamond surface covered with gold did not react with manganese powder, and only six spots where gold was removed reacted with manganese under vacuum at a pressure of 8 × 10 −4 Pa (to prevent oxidation) by heating with near-infrared radiation.Layered manganese carbides formed on diamond (110) by the radiation heating at 693 K.The measured magnetic flux density from the modified diamond (110) by a Hall-effect sensor was greater than that of geomagnetism, with a maximum value of 73 μT at the

T
. Yamazaki, R. Ninomiya DOI: 10.4236/msa.2017.88045643 Materials Sciences and Applications specific diamond plane producing nanoscopic layers provides spontaneous magnetization.Using infrared radiation heating, the surface of diamond decomposes by the molecular vibrations, desorbing carbon dioxide gas and hydrocarbons from the surface [5].

Figure 1 .
Figure 1.Schematic illustration of the processing of diamond (110) covered with a gold film.

Figure 2 .
Figure 2. Schematic illustration of infrared heating of the device.

Figure 3 .
Figure 3. Appearance of the modified surface and the hexagonal spots showing the magnet formation.

Figure 4 .
Figure 4. X-ray diffraction pattern after the surface modification of diamond (110) with the manganese powder.

Figure 5
Figure5shows the results of the measured magnetic flux densities on spot A

Figure 5 .
Figure 5. Magnetic flux densities on the modified diamond (110) with remaining gold film and with the gold film removed.

Table 2 .
Magnetic flux densities measured at the six spots.