This research was partially supported by the Ministry of Science, ICT, and Future Planning (MSIP), Korea, under the Information Technology Research Center (ITRC) support program (IITP-2017-2015-0-00385) and the ICT R&#38;D program (10043464, Development of quantum repeater technology for the application to communication systems), supervised by the Institute for Information &#38; Communications Technology Promotion (IITP).

<ol>
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The authors have nothing to disclose.

This paper presented a method for trapping ions using microfabricated surface ion traps. The construction of an ion trapping system requires experiences in various research fields but has not previously been described in detail. This paper provided detailed procedures for microfabricating a trap chip as well as for constructing an experimental setup to trap ions for the first time. This paper also provided detailed procedures for trapping 174Yb+ ions and experimenting with trapped ions.
A significant obstacle faced in the microfabrication procedures is the deposition of the dielectric layer, with a thickness of over 10 &#181;m. During the deposition process of the thick dielectric layer, residual stress can build up, which can cause damage to the dielectric film or even break the wafer. To reduce the residual stress, which is generally compressive, a slow deposition rate should be used40. In our case, a compressive stress of 110.4 MPa was measured with the deposition conditions of 540 sccm of SiH4 gas flow rate, 140 W of RF power, and 1.9 Torr of pressure at 5-&#181;m film thickness. However, these process conditions provide only a rough reference, since these conditions can vary significantly for different equipment. In order to reduce the effects of accumulated stress, 3.5 &#181;m-thick SiO2 films were deposited alternatingly on both sides of the wafer in the presented method. The required thickness of the dielectric layer can be reduced if a smaller RF voltage amplitude and hence a shallower trap depth is chosen. However, a shallower trap depth easily leads to the escape of trapped ions, so the fabrication of thicker dielectric layers, which can withstand higher RF voltages, is more desirable.
There are some limitations to the fabrication method presented in this paper. The lengths of the overhangs are not sufficient to completely hide the dielectric sidewalls from the trapped ions, as shown in Figure 7f. Furthermore, the sidewalls of the oxide pillars are jagged, increasing the exposed area of the dielectric sidewalls compared to the vertical oxide pillar. For example, in the case of the sidewall of the inner DC rail near the loading slot with a 5 &#181;m uniform overhang, it is calculated that 33% of the dielectric surface is exposed to the trapped ion position of the vertical sidewall. In the jagged-edge case, more than 70% of the sidewall area is exposed. These non-ideal fabrication results can induce additional stray fields from the exposed dielectrics, but the effects have not been quantitatively measured. Nevertheless, the fabricated chip as reported above has been successfully used in ion trapping and qubit manipulation experiments. In addition, the trap chip presented in this paper has exposed silicon sidewalls near the loading slot. Native oxide can grow on the silicon surfaces and can result in additional stray fields. Therefore, it is recommended to protect the silicon substrate with an additional metal layer, as in33.
To trap 174Yb+ ions, the frequencies of the lasers should be stabilized within a few tens of MHz, and a few different methods are discussed in advanced setups38,41. However, for the simple setup discussed in this paper, initial trapping is possible only with stabilization using a wavelength meter.
This paper provided a protocol to trap 174Yb+ ions using a microfabricated surface ion-trap chip. Although the protocol for trapping 171Yb+ ions is not specifically discussed, the experimental setup described in this paper can be also used to trap 171Yb+ ions and to manipulate the qubit state of the 171Yb+ ions to obtain Rabi oscillation results (shown in Figure 10). This can be done by adding several optical modulators to the output of the lasers and by using a microwave setup, as described in the Supplementary Document.
In conclusion, the experimental methods and results presented in this paper can be used to develop various quantum information applications using surface ion traps.

A Paul trap can confine charged particles, including ions in empty space, using a combination of a static electric field and a varying electric field oscillating at radio frequency (RF), and the quantum states of the ions confined in the trap can be measured and controlled1,2,3. Such ion traps were originally developed for precise measurement applications, including optical clocks and mass spectroscopy4,5,6. In recent years, these ion traps have also been actively explored as a physical platform to implement the quantum information processing attributed to the desirable characteristics of trapped ions, such as long coherence times, ideal isolation in an ultra-high vacuum (UHV) environment, and the feasibility of individual qubit manipulation7,8,9,10. Since Kielpinski et al.11 proposed a scalable ion-trap architecture that can be used to develop quantum computers, various types of surface traps, including junction traps12,13, multi-zone trap chips14, and 2-d array traps15,16,17, have been developed using semiconductor process-derived microfabrication methods18,19,20,21. Large-scale quantum information processing systems based on the surface traps have also been discussed22,23,24.
This paper presents experimental methods for trapping ions using microfabricated surface ion traps. More specifically, a procedure for fabricating surface ion traps and a detailed procedure for trapping ions using the fabricated traps are described. In addition, detailed descriptions of various practical techniques for setting up the experimental system and trapping ions are provided in the Supplementary Document.
The methodology for microfabricating a surface ion trap is given in step 1. Figure 1 shows a simplified schematic of a surface ion trap. The electric fields generated by the voltage applied to the electrodes in the transverse plane are also shown25. An RF voltage is applied to the pair of RF electrodes, while all other electrodes are kept at RF ground; the ponderomotive potential26 generated by the RF voltage confines the ions to the radial direction. The direct current (DC) voltage applied to the multiple DC electrodes outside the RF electrodes confine the ions to the longitudinal direction. The inner rails between the RF electrodes are designed to help tilt the principal axes of the total potential in the transverse plane. The methodology for designing a DC voltage set is included in the Supplementary Document. In addition, more details for designing the essential geometric parameters of surface ion-trap chips can be found in27,28,29,30,31.
The fabrication method introduced in step 1 was designed considering the following aspects. First, the dielectric layer between the electrode layer and the ground layer should be sufficiently thick to prevent electrical breakdown between the layers. Generally, the thickness should be over 10&#181;m. During the deposition of the thick dielectric layer, the residual stress from the deposited films can cause bowing of the substrate or damages to the deposited films. Thus, controlling the residual stress is one of the key techniques in the fabrication of the surface ion traps. Second, the exposure of the dielectric surfaces to the ion position should be minimized because stray charges can be induced on the dielectric material by scattered ultraviolet (UV) lasers, which in turn results in a random shift of ion position. The exposed area can be reduced by designing overhang electrode structures. It has been reported that surface ion traps with electrode overhangs are resistant to charging under typical experimental conditions32. Third, all the materials, including various deposited films, should be able to withstand 200 &#176;C baking for approximately 2 weeks, and the amount of outgassing from all materials should be compatible with UHV environments. The design of the surface ion-trap chips microfabricated in this paper is based on the trap design from33, which was successfully used in various experiments32,33,34,35. Note that this design includes a slot in the middle of the chip for loading neutral atoms, which are later photo-ionized for trapping.
After the fabrication of the ion-trap chip, the chip is mounted and electrically connected to the chip carrier using gold bonding wires. The chip carrier is then installed in a UHV chamber. A detailed procedure for preparing a trap chip package and the design of the UHV chamber are provided in the Supplementary Document.
Preparation of the optical and electrical equipment, as well as the experimental procedures for trapping ions, are explained in detail in step 2. The ions trapped by the ponderomotive potential are generally subject to the fluctuation of the surrounding electric field, which continuously increases the average kinetic energy of the ions. Laser cooling based on Doppler shift can be used to remove the excess energy from the motion of the ions. Figure 2 shows the simplified energy-level diagrams of a 174Yb+ ion and a neutral 174Yb atom. Doppler cooling of 174Yb+ ions requires a 369.5-nm laser and a 935-nm laser, while photo-ionization of neutral 174Yb atoms requires a 399-nm laser. Steps 2.2 and 2.3 describe an efficient method to align these lasers to the surface ion-trap chip and a procedure to find the proper conditions for photo-ionization. After the optical and electrical components are prepared, trapping ions is relatively straightforward. The experimental sequence for trapping ions is presented in step 2.4.

<table border="0" cellpadding="0" cellspacing="0" width="1425">
	<tbody>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">photoresist used for 2-&#956;m spin coating</td>
			<td style="width:123px;">AZ Materials</td>
			<td style="width:381px;">AZ7220</td>
			<td style="width:629px;">Discontinued. Easily replaced by other alternative photoresist product.</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">photoresist used for 6-&#956;m spin coating</td>
			<td>AZ Materials</td>
			<td>AZ4620</td>
			<td>Discontinued. Easily replaced by other alternative photoresist product.</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">ceramic chip carrier</td>
			<td>NTK</td>
			<td>IPKX0F1-8180BA</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">epoxy compound</td>
			<td>Epotek</td>
			<td>353ND</td>
			<td></td>
		</tr>
		<tr height="45">
			<td height="45" style="height:45px;width:293px;">Plasma enhanced chemical vapor deposition (PECVD) system</td>
			<td style="width:123px;">Oxford Instruments</td>
			<td style="width:381px;">PlasmaPro System100</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="56">
			<td height="56" style="height:56px;width:293px;">Low pressure chemical vapor deposition (LPCVD) system</td>
			<td style="width:123px;">Centrotherm</td>
			<td style="width:381px;">E-1200</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">Furnace</td>
			<td style="width:123px;">Seltron</td>
			<td style="width:381px;">SHF-150</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">Sputter</td>
			<td style="width:123px;">Muhan Vacuum</td>
			<td style="width:381px;">MHS-1500</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">Manual aligner</td>
			<td style="width:123px;">Karl-Suss</td>
			<td style="width:381px;">MA-6</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">Deep Si etcher</td>
			<td style="width:123px;">Plasma-Therm</td>
			<td style="width:381px;">SLR-770-10R-B</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="53">
			<td height="53" style="height:53px;width:293px;">Inductive coupled plasma (ICP) etcher</td>
			<td style="width:123px;">Oxford Instruments</td>
			<td style="width:381px;">PlasmaPro System100 Cobra</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">Reactive ion etching (RIE) etcher</td>
			<td style="width:123px;">Applied Materials</td>
			<td style="width:381px;">P-5000</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">Boundary element method (BEM) software</td>
			<td style="width:123px;">CPO Ltd.</td>
			<td style="width:381px;">Charged Particle Optics</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">Single crystaline (100) silicon wafer</td>
			<td style="width:123px;">STC</td>
			<td style="width:381px;">4SWP02</td>
			<td style="width:629px;">100 mm / (100) / P-type / SSP / 525&#177;25 &#956;m</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">metal tubes</td>
			<td>Mcmaster-carr</td>
			<td>89935K69</td>
			<td>316 Stainless Steel Tubing, 0.042&#34; OD, 0.004&#34; Wall Thickness</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">Yb piece</td>
			<td>Goodfellow</td>
			<td style="width:381px;">YB005110</td>
			<td>Ytterbium wire, purity 99.9%</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">enriched 171Yb</td>
			<td>Oak Ridge National Laboratory</td>
			<td>Yb-171</td>
			<td>https://www.isotopes.gov/catalog/product.php?element=Ytterbium</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">tantalum foil</td>
			<td>The Nilaco Corporation</td>
			<td>TI-453401</td>
			<td>0.25x130x100mm 99.5%</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">Kapton-insulated copper wire</td>
			<td>Accu-glass</td>
			<td>18AWG (silver plated copper wire kapton insulted)</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">residual gas analyzer (RGA)</td>
			<td>SRS</td>
			<td>RGA200</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">turbo pump</td>
			<td>Agilent</td>
			<td>Twistorr84 FS</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">all-metal valve</td>
			<td>KJL</td>
			<td>manual SS All-Metal Angle Valves (CF flanged)</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">Leak detector (used as a rough pump)</td>
			<td>Varian</td>
			<td>PD03</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">ion gauges</td>
			<td>Agilent</td>
			<td>UHV-24p</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">ion pump</td>
			<td>Agilent</td>
			<td>VacIon Plus 20</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">NEG pump</td>
			<td>SAES Getters</td>
			<td>CapaciTorr D400</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">spherical octagon</td>
			<td>Kimball Physics</td>
			<td>MCF600-SphOct-F2C8</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">ZIF socket</td>
			<td>Tactic Electronics</td>
			<td>P/N 100-4680-002A</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">multi-pin feedthroughs</td>
			<td>Accu-Glass</td>
			<td>6-100531</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">25 D-sub gender adapters</td>
			<td>Accu-Glass</td>
			<td>104101</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">Recessed viewport</td>
			<td>Culham Centre for Fusion Energy</td>
			<td style="width:381px;">100CF 316LN+20.9 Re-Entrant 316 (Custom order)</td>
			<td style="width:629px;">Disc material: 60cv Fused Silica 4mm THK, TWE Lambda 1/10, 20/10 Scratch-Dig</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">Recessed viewport AR coating</td>
			<td style="width:123px;">LaserOptik</td>
			<td style="width:381px;">AR355nm/0-6&#176; HT370-650nm/0-36&#176; on UHV (Custom order)</td>
			<td style="width:629px;">AR coating was performed in the middle of the fabrication of the recessed viewport</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">Digital-analog converter</td>
			<td style="width:123px;">AdLink</td>
			<td style="width:381px;">PCIe-6216V-GL</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">369.5nm laser</td>
			<td style="width:123px;">Toptica</td>
			<td style="width:381px;">TA-SHG Pro</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">369.5nm laser</td>
			<td style="width:123px;">Moglabs</td>
			<td style="width:381px;">ECD004 + 370LD10 + DLC102/HC</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">399nm laser</td>
			<td style="width:123px;">Toptica</td>
			<td style="width:381px;">DL 100</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">935nm laser</td>
			<td style="width:123px;">Toptica</td>
			<td style="width:381px;">DL 100</td>
			<td style="width:629px;"></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">369.5nm &#38; 399nm optical fiber</td>
			<td style="width:123px;">Coherent</td>
			<td style="width:381px;">NUV-320-K1</td>
			<td style="width:629px;">Patch cables are connectorized by Costal Connections.</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">935nm optical fiber</td>
			<td style="width:123px;">GouldFiber Optics</td>
			<td style="width:381px;">PSK-000626</td>
			<td style="width:629px;">50/50 fiber beam splitter made of Corning HI-780 single mode fiber to combine 935nm and 638nm together.</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">Wavelength meter</td>
			<td>High Finesse</td>
			<td>WSU-2</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">temporary mirror</td>
			<td>Thorlabs</td>
			<td>PF10-03-P01</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">Dichroic mirror</td>
			<td>Semrock</td>
			<td>FF647-SDi01-25x36</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">369.5nm &#38; 399nm collimator</td>
			<td>Micro Laser Systems</td>
			<td>FC5-UV-T/A</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">935nm collimator</td>
			<td>Sch&#228;fter + Kirchhoff</td>
			<td>60FC-0-M8-10</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">369.5nm focusing lens</td>
			<td style="width:123px;">CVI</td>
			<td style="width:381px;">PLCX-25.4-77.3-UV-355-399</td>
			<td>Focal length: ~163mm @ 369.5nm</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;width:293px;">399nm &#38; 935nm focusing lens</td>
			<td style="width:123px;">CVI</td>
			<td style="width:381px;">PLCX-25.4-64.4-UV-355-399</td>
			<td style="width:629px;">Focal length: ~137mm @ 399nm, ~143mm @ 935nm</td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">imaging lens</td>
			<td>Photon Gear</td>
			<td>P/N 15470</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">369.5nm bandpass filter</td>
			<td>Semrock</td>
			<td>FF01-370/6-25</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">399nm bandpass filter</td>
			<td>Semrock</td>
			<td>FF01-395/11-25</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">IR filter</td>
			<td>Semrock</td>
			<td>FF01-650/SP-25</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">EMCCD camera</td>
			<td>Andor Technology</td>
			<td>DU-897U-CS0-EXF</td>
			<td></td>
		</tr>
		<tr height="23">
			<td height="23" style="height:23px;">PMT</td>
			<td>Hamamatsu</td>
			<td>H10682-210</td>
			<td></td>
		</tr>
	</tbody>
</table>

experimental methods for trapping ions using microfabricated surface ion traps

Ions trapped in a quadrupole Paul trap have been considered one of the strong physical candidates to implement quantum information processing. This is due to their long coherence time and their capability to manipulate and detect individual quantum bits (qubits). In more recent years, microfabricated surface ion traps have received more attention for large-scale integrated qubit platforms. This paper presents a microfabrication methodology for ion traps using micro-electro-mechanical system (MEMS) technology, including the fabrication method for a 14 &#181;m-thick dielectric layer and metal overhang structures atop the dielectric layer. In addition, an experimental procedure for trapping ytterbium (Yb) ions of isotope 174 (174Yb+) using 369.5 nm, 399 nm, and 935 nm diode lasers is described. These methodologies and procedures involve many scientific and engineering disciplines, and this paper first presents the detailed experimental procedures. The methods discussed in this paper can easily be extended to the trapping of Yb ions of isotope 171 (171Yb+) and to the manipulation of qubits.

Figure 7 shows the scanning electron micrographs (SEM)&#160;of the fabricated ion-trap chip. The RF electrodes, inner DC electrodes, outer DC electrodes, and loading slot were successfully fabricated. The sidewall profile of the dielectric pillar became jagged because the PECVD oxide was deposited in several steps. The multiple deposition steps were used to minimize the effects of residual stress from thick oxide films. This is further described in the Discussion.

Figure 8 shows the EMCCD image of five 174Yb+ ions trapped using the microfabricated ion-trap chip. The trapped ions can last for more than 24 h with continuous Doppler cooling. The number of trapped ions can be adjusted between 1 and 20 by changing the applied DC voltage set. This experimental setup is very reliable and robust and has currently been in operation for 50 months.
Figure 9 shows the shuttling of trapped ions along the axial direction. The ion position in Figure 9b is displaced from that in Figure 9a through the adjustment of the position of the DC potential minimum by changing the DC voltages.
Figure 10 shows preliminary results of Rabi oscillation experiments with a 171Yb+ ion. To obtain the results, the additional setups described in the Supplementary Document were used. The results were included to show a potential application of the experimental setup explained in this paper.
<img alt="Figure 1" class="xfigimg" src="/files/ftp_upload/56060/56060fig1.jpg" /> 
Figure 1: Schematic of the surface ion trap. (a) The red dots represent the trapped ions. The brown and yellow electrodes indicate the RF and DC electrodes, respectively. The gray arrows show the direction of the electric field during the positive phase of the RF voltage. Note that the schematic is not drawn to scale. (b) The vertical dimensions of the electrode structure. (c) The lateral dimensions of the electrode structure. <a href="https://cloudflare-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/56060/56060fig1large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
<img alt="Figure 2" class="xfigimg" src="/files/ftp_upload/56060/56060fig2.jpg" /> 
Figure 2: Simplified energy-level diagrams of a 174Yb+ ion and a neutral 174Yb atom. (a) When a 369.5 nm laser is detuned to the red side (lower frequency) of the resonance, a cycling transition between 2P1/2 and 2S1/2 reduces the kinetic energy of the ion because of the Doppler effect. Occasionally, a small but finite branching ratio makes the electron decay from 2P1/2 to 2D3/2, and a 935-nm laser is required to return the electron back to the main cycling transition. The electron can also decay into a 2F7/2 state once per hour, on average, and a 638 nm laser can pump it out of the 2F7/2 state, but this is not necessary for a simple system38. The values in the ket notation represent the projections of the total angular momenta J along the quantization axis mJ. (b) To ionize neutral atoms evaporated from the oven, a two-photon absorption process was used39. A 399 nm laser excited an electron to 1P1 state, and the 369.5 nm photon for Doppler cooling had more energy than necessary to remove the excited electron from the ion. <a href="https://cloudflare-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/56060/56060fig2large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
<img alt="Figure 3" class="xfigimg" src="/files/ftp_upload/56060/56060fig3.jpg" /> 
Figure 3: Fabrication process flow of a surface ion trap. (a) Thermal oxidation to grow a 5,000 &#197;-thick SiO2 layer and LPCVD of a 2,000 &#197;-thick Si3N4 layer. (b) Deposition and ICP etching of a 1.5 &#181;m-thick sputtered Al layer. (c) Deposition of a 14 &#181;m-thick SiO2 layer on the both sides of the wafer using PECVD processes. (d) Patterning of the 14 &#181;m-thick SiO2 layer deposited on the front of the wafer using an RIE process (e) Patterning of the 14 &#181;m-thick SiO2 layer deposited on the back of the wafer using an RIE process. (f) Deposition of a 1.5 &#181;m-thick sputtered Al layer and a 1 &#181;m-thick PECVD SiO2 layer. (g) Patterning of the 1.5 &#181;m-thick Al layer using an ICP process and the 1 &#181;m-thick SiO2 layer using an RIE process. (h) Patterning of the 14 &#181;m-thick SiO2 layer deposited on the front of the wafer using an RIE process. (i) Patterning of the 5,000 &#197;-thick SiO2 layer and the 2,000 &#197;-thick Si3N4 layer using an RIE process. (j) DRIE of the silicon substrate 450 &#181;m from the back of the wafer. (k) Wet-etching of the SiO2 layer on the Al electrodes and the sidewalls of the dielectric pillars. (l) Penetration of the silicon substrate from the front through a DRIE process. Note that the schematics are not drawn to scale. <a href="https://cloudflare-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/56060/56060fig3large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
<img alt="Figure 4" class="xfigimg" src="/files/ftp_upload/56060/56060fig4.jpg" /> 
Figure 4: An example of the DC voltage set used to trap ions. The voltages applied to the inner rails can compensate for the asymmetric electric field in the horizontal direction to tilt the principal axes of the total potential in the transverse plane. The axial trap frequency generated by the voltage set was 550 kHz. <a href="https://cloudflare-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/56060/56060fig4large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
<img alt="Figure 5" class="xfigimg" src="/files/ftp_upload/56060/56060fig5v2.jpg" /> 
Figure 5: Schematic of the optical setup. Three diode lasers are aligned to overlap at the trapping position. The recessed viewport of the UHV chamber allows the imaging lens to be placed as close as possible to the chip surface. A flip-mirror placed between the imaging lens and the EMCCD allows for the selective monitoring of the ion fluorescence using either a photon multiplied tube (PMT) or an EMCCD. <a href="https://cloudflare-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/56060/56060fig5v2large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
<img alt="Figure 6" class="xfigimg" src="/files/ftp_upload/56060/56060fig6.jpg" /> 
Figure 6: Images of the constructed optical setup. (a) A coil is wound around the front viewport of the chamber to generate a magnetic field, which can break degenerate energy levels of ytterbium ions. (b) The optical setup for steering the 399 nm and 935 nm beams. The red and green lines indicate the beam path of the 935 nm and 399 nm lasers, respectively. (c) The configuration of the imaging system, including the flip-mirror, the imaging lens, the EMCCD, and the PMT. The path of the fluorescence emitted from the trapped ions can be determined by the flip-mirror. The green and white arrows indicate the path of the fluorescence when being monitored by the EMCCD and the PMT, respectively. <a href="https://cloudflare-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/56060/56060fig6large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
<img alt="Figure 7" class="xfigimg" src="/files/ftp_upload/56060/56060fig7.jpg" /> 
Figure 7: Fabrication results of the surface ion trap. (a) Overview of the chip layout. (b) A magnified view of the chip layout, which shows the multiple outer DC electrodes. (c) A magnified view of chip layout, which shows the loading slot. (d) A cross-sectional view of the trapping region before penetrating the loading slot. (e) A cross-sectional view of the trapping region after penetrating the loading slot. (f) A magnified cross-sectional view of the oxide pillar. The oxide pillars have jagged walls, and the lengths of the overhang are not sufficient, which is attributed to the non-uniform etch rate of the SiO2 at the interfaces between the separately deposited 3.5 &#181;m-thick SiO2 layers. (g) A top view of a wire-bonding pad of a DC electrode. (h) A cross-sectional view of a via. Inclined profiles of the oxide pillars allow for the connection of the DC electrode and the ground layer during the deposition of the Al layer on the sidewall of the oxide pillar instead of filling the via holes with an electroplating process. <a href="https://cloudflare-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/56060/56060fig7large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
<img alt="Figure 8" class="xfigimg" src="/files/ftp_upload/56060/56060fig8.jpg" /> 
Figure 8: An EMCCD image of five 174Yb+ ions trapped on the microfabricated ion-trap chip. The image of the surface trap electrode structure was taken separately, and the images of the trapped ion and of the electrodes were combined for clarity. The intensity legend applies only to the pixels in the box. The thick arrow shows the beam path of the 369.5 nm laser and the thin arrows represent the x- and z-components of the momentum of the photon. <a href="https://cloudflare-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/56060/56060fig8large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
<img alt="Figure 9" class="xfigimg" src="/files/ftp_upload/56060/56060fig9.jpg" /> 
Figure 9: Adjustment of the axial potential of the trapped ions in a linear chain. (a) Seven ions at the center of the trap. (b) The ions were shuttled tens of micrometers. (c) The ion string squeezed in the axial direction. This figure is best viewed as a movie, which is separately uploaded. <a href="https://cloudflare-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/56060/56060fig9large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
<img alt="Figure 10" class="xfigimg" src="/files/ftp_upload/56060/56060fig10.jpg" /> 
Figure 10: Experimental results of Rabi oscillations between the |0<img alt="Image 1" src="/files/ftp_upload/56060/56060img1.jpg" /> and |1<img alt="Image 1" src="/files/ftp_upload/56060/56060img1.jpg" /> states. |0<img alt="Image 1" src="/files/ftp_upload/56060/56060img1.jpg" /> is defined as the 2S1/2|F=0, mF=0<img alt="Image 1" src="/files/ftp_upload/56060/56060img1.jpg" /> state of the 171Yb+ ion, and |1<img alt="Image 1" src="/files/ftp_upload/56060/56060img1.jpg" /> is defined as the 2S1/2|F=1, mF=0<img alt="Image 1" src="/files/ftp_upload/56060/56060img1.jpg" /> state. The Rabi oscillation is induced by a 12.6428-GHz microwave. Bloch spheres above the plot show the corresponding quantum states at different times. <a href="https://cloudflare-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/56060/56060fig10large.jpg" target="_blank">Please click here to view a larger version of this figure.</a>
Supplementary Document: <a href="https://cloudflare-jove-com.remotexs.ntu.edu.sg/files/ftp_upload/56060/jove-56060_Supplementary_Document.pdf" target="_blank">Please click here to download this document.</a>

Watch this Scientific Journal Video about Experimental Methods for Trapping Ions Using Microfabricated Surface Ion Traps at JoVE.com

Experimental Methods for Trapping Ions Using Microfabricated Surface Ion Traps

This paper presents a microfabrication methodology for surface ion traps, as well as a detailed experimental procedure for trapping ytterbium ions in a room-temperature environment.

Ions trapped in a quadrupole Paul trap have been considered one of the strong physical candidates to implement quantum information processing. This is due ...

experimental-methods-for-trapping-ions-using-microfabricated-surface

Nanyang Technological University

Research

JoVE Journal

Engineering

13.4K Views.  Seoul National University. This paper presents a microfabrication methodology for surface ion traps, as well as a detailed experimental procedure for trapping ytterbium ions in a room-temperature environment.

Video: Experimental Methods for Trapping Ions Using Microfabricated Surface Ion Traps

Optical Trapping of Nanoparticles

Optical trapping is a technique for immobilizing and manipulating small objects in a gentle way using light, and it has been widely applied in trapping and manipulating small biological particles. Ashkin and co-workers first demonstrated optical tweezers using a single focused beam1. The single beam trap can be described accurately using the perturbative gradient force formulation in the case of small Rayleigh regime particles1. In the perturbative regime, the optical power required for trapping a particle scales as the inverse fourth power of the particle size. High optical powers can damage dielectric particles and cause heating. For instance, trapped latex spheres of 109 nm in diameter were destroyed by a 15 mW beam in 25 sec1, which has serious implications for biological matter2,3.
A self-induced back-action (SIBA) optical trapping was proposed to trap 50 nm polystyrene spheres in the non-perturbative regime4. In a non-perturbative regime, even a small particle with little permittivity contrast to the background can influence significantly the ambient electromagnetic field and induce a large optical force. As a particle enters an illuminated aperture, light transmission increases dramatically because of dielectric loading. If the particle attempts to leave the aperture, decreased transmission causes a change in momentum outwards from the hole and, by Newton's Third Law, results in a force on the particle inwards into the hole, trapping the particle. The light transmission can be monitored; hence, the trap can become a sensor. The SIBA trapping technique can be further improved by using a double-nanohole structure.
The double-nanohole structure has been shown to give a strong local field enhancement5,6. Between the two sharp tips of the double-nanohole, a small particle can cause a large change in optical transmission, thereby inducing a large optical force. As a result, smaller nanoparticles can be trapped, such as 12 nm silicate spheres7 and 3.4 nm hydrodynamic radius bovine serum albumin proteins8. In this work, the experimental configuration used for nanoparticle trapping is outlined. First, we detail the assembly of the trapping setup which is based on a Thorlabs Optical Tweezer Kit. Next, we explain the nanofabrication procedure of the double-nanohole in a metal film, the fabrication of the microfluidic chamber and the sample preparation. Finally, we detail the data acquisition procedure and provide typical results for trapping 20 nm polystyrene nanospheres.

The following setup approach details low power optical trapping of dielectric nanoparticles using a double-nanohole in metal film.

Optical trapping is a technique for immobilizing and manipulating small objects in a gentle way using light, and it has been widely applied in trapping ...

Characterization of Surface Modifications by White Light Interferometry: Applications in Ion Sputtering, Laser Ablation, and Tribology Experiments

In materials science and engineering it is often necessary to obtain quantitative measurements of surface topography with micrometer lateral resolution. From the measured surface, 3D topographic maps can be subsequently analyzed using a variety of software packages to extract the information that is needed.
In this article we describe how white light interferometry, and optical profilometry (OP) in general, combined with generic surface analysis software, can be used for materials science and engineering tasks. In this article, a number of applications of white light interferometry for investigation of surface modifications in mass spectrometry, and wear phenomena in tribology and lubrication are demonstrated. We characterize the products of the interaction of semiconductors and metals with energetic ions (sputtering), and laser irradiation (ablation), as well as ex situ measurements of wear of tribological test specimens.
Specifically, we will discuss:
<ol class="lroman">
	<li>Aspects of traditional ion sputtering-based mass spectrometry such as sputtering rates/yields measurements on Si and Cu and subsequent time-to-depth conversion.</li>
	<li>Results of quantitative characterization of the interaction of femtosecond laser irradiation with a semiconductor surface. These results are important for applications such as ablation mass spectrometry, where the quantities of evaporated material can be studied and controlled via pulse duration and energy per pulse. Thus, by determining the crater geometry one can define depth and lateral resolution versus experimental setup conditions.</li>
	<li>Measurements of surface roughness parameters in two dimensions, and quantitative measurements of the surface wear that occur as a result of friction and wear tests.</li>
</ol>
Some inherent drawbacks, possible artifacts, and uncertainty assessments of the white light interferometry approach will be discussed and explained.

White light microscope interferometry is an optical, noncontact and quick method for measuring the topography of surfaces. It is shown how the method can be applied toward mechanical wear analysis, where wear scars on tribological test samples are analyzed; and in materials science to determine ion beam sputtering or laser ablation volumes and depths.

In materials science and engineering it is often necessary to obtain quantitative measurements of surface topography with micrometer lateral resolution. ...

Characterization of Electrode Materials for Lithium Ion and Sodium Ion Batteries Using Synchrotron Radiation Techniques

Intercalation compounds such as transition metal oxides or phosphates are the most commonly used electrode materials in Li-ion and Na-ion batteries. During insertion or removal of alkali metal ions, the redox states of transition metals in the compounds change and structural transformations such as phase transitions and/or lattice parameter increases or decreases occur. These behaviors in turn determine important characteristics of the batteries such as the potential profiles, rate capabilities, and cycle lives. The extremely bright and tunable x-rays produced by synchrotron radiation allow rapid acquisition of high-resolution data that provide information about these processes. Transformations in the bulk materials, such as phase transitions, can be directly observed using X-ray diffraction (XRD), while X-ray absorption spectroscopy (XAS) gives information about the local electronic and geometric structures (e.g.&#160;changes in redox states and bond lengths). In situ experiments carried out on operating cells are particularly useful because they allow direct correlation between the electrochemical and structural properties of the materials. These experiments are time-consuming and can be challenging to design due to the reactivity and air-sensitivity of the alkali metal anodes used in the half-cell configurations, and/or the possibility of signal interference from other cell components and hardware. For these reasons, it is appropriate to carry out ex situ experiments (e.g.&#160;on electrodes harvested from partially charged or cycled cells) in some cases. Here, we present detailed protocols for the preparation of both ex situ and in situ samples for experiments involving synchrotron radiation and demonstrate how these experiments are done.

We describe the use of synchrotron X-ray absorption spectroscopy (XAS) and X-ray diffraction (XRD) techniques to probe details of intercalation/deintercalation processes in electrode materials for Li-ion and Na-ion batteries. Both in situ and ex situ experiments are used to understand structural behavior relevant to the operation of devices

Intercalation compounds such as transition metal oxides or phosphates are the most commonly used electrode materials in Li-ion and Na-ion batteries. ...

In Situ Neutron Powder Diffraction Using Custom-made Lithium-ion Batteries

Li-ion batteries are widely used in portable electronic devices and are considered as promising candidates for higher-energy applications such as electric vehicles.1,2 However, many challenges, such as energy density and battery lifetimes, need to be overcome before this particular battery technology can be widely implemented in such applications.3 This research is challenging, and we outline a method to address these challenges using in situ NPD to probe the crystal structure of electrodes undergoing electrochemical cycling (charge/discharge) in a battery. NPD data help determine the underlying structural mechanism responsible for a range of electrode properties, and this information can direct the development of better electrodes and batteries.
We briefly review six types of battery designs custom-made for NPD experiments and detail the method to construct the &#8216;roll-over&#8217; cell that we have successfully used on the high-intensity NPD instrument, WOMBAT, at the Australian Nuclear Science and Technology Organisation (ANSTO). The design considerations and materials used for cell construction are discussed in conjunction with aspects of the actual in situ NPD experiment and initial directions are presented on how to analyze such complex in situ data.

In Situ Neutron Powder Diffraction Using Custom-made Lithium-ion Batteries

We describe the design and construction of an electrochemical cell for the examination of electrode materials using in situ neutron powder diffraction (NPD). We briefly comment on alternate in situ NPD cell designs and discuss methods for the analysis of the corresponding in situ NPD data produced using this cell.

Li-ion batteries are widely used in portable electronic devices and are considered as promising candidates for higher-energy applications such as electric ...

Surface Enhanced Raman Spectroscopy Detection of Biomolecules Using EBL Fabricated Nanostructured Substrates

Fabrication and characterization of conjugate nano-biological systems interfacing metallic nanostructures on solid supports with immobilized biomolecules is reported. The entire sequence of relevant experimental steps is described, involving the fabrication of nanostructured substrates using electron beam lithography, immobilization of biomolecules on the substrates, and their characterization utilizing surface-enhanced Raman spectroscopy (SERS). Three different designs of nano-biological systems are employed, including protein A, glucose binding protein, and a dopamine binding DNA aptamer. In the latter two cases, the binding of respective ligands, D-glucose and dopamine, is also included. The three kinds of biomolecules are immobilized on nanostructured substrates by different methods, and the results of SERS imaging are reported. The capabilities of SERS to detect vibrational modes from surface-immobilized proteins, as well as to capture the protein-ligand and aptamer-ligand binding are demonstrated. The results also illustrate the influence of the surface nanostructure geometry, biomolecules immobilization strategy, Raman activity of the molecules and presence or absence of the ligand binding on the SERS spectra acquired.

We describe the fabrication and characterization of nano-biological systems interfacing nanostructured substrates with immobilized proteins and aptamers. The relevant experimental steps involving lithographic fabrication of nanostructured substrates, bio-functionalization, and surface-enhanced Raman spectroscopy (SERS) characterization, are reported. SERS detection of surface-immobilized proteins, and probing of protein-ligand and aptamer-ligand binding is demonstrated.

Fabrication and characterization of conjugate nano-biological systems interfacing metallic nanostructures on solid supports with immobilized biomolecules ...

Speciation and Bioavailability Measurements of Environmental Plutonium Using Diffusion in Thin Films

The biological uptake of plutonium (Pu) in aquatic ecosystems is of particular concern since it is an alpha-particle emitter with long half-life which can potentially contribute to the exposure of biota and humans. The diffusive gradients in thin films technique is introduced here for in-situ measurements of Pu bioavailability and speciation. A diffusion cell constructed for laboratory experiments with Pu and the newly developed protocol make it possible to simulate the environmental behavior of Pu in model solutions of various chemical compositions. Adjustment of the oxidation states to Pu(IV) and Pu(V) described in this protocol is essential in order to investigate the complex redox chemistry of plutonium in the environment. The calibration of this technique and the results obtained in the laboratory experiments enable to develop a specific DGT device for in-situ Pu measurements in freshwaters. Accelerator-based mass-spectrometry measurements of Pu accumulated by DGTs in a karst spring allowed determining the bioavailability of Pu in a mineral freshwater environment. Application of this protocol for Pu measurements using DGT devices has a large potential to improve our understanding of the speciation and the biological transfer of Pu in aquatic ecosystems.

The technique of diffusive gradients in thin films (DGT) is proposed for speciation studies of plutonium. This protocol describes diffusion experiments probing the behavior of Pu(IV) and Pu(V) in presence of organic matter. DGTs deployed in a karstic spring allow assessment of the bioavailability of Pu.

The biological uptake of plutonium (Pu) in aquatic ecosystems is of particular concern since it is an alpha-particle emitter with long half-life which can ...

Advanced Experimental Methods for Low-temperature Magnetotransport Measurement of Novel Materials

Novel electronic materials are often produced for the first time by synthesis processes that yield bulk crystals (in contrast to single crystal thin film synthesis) for the purpose of exploratory materials research. Certain materials pose a challenge wherein the traditional bulk Hall bar device fabrication method is insufficient to produce a measureable device for sample transport measurement, principally because the single crystal size is too small to attach wire leads to the sample in a Hall bar configuration. This can be, for example, because the first batch of a new material synthesized yields very small single crystals or because flakes of samples of one to very few monolayers are desired. In order to enable rapid characterization of materials that may be carried out in parallel with improvements to their growth methodology, a method of device fabrication for very small samples has been devised to permit the characterization of novel materials as soon as a preliminary batch has been produced. A slight variation of this methodology is applicable to producing devices using exfoliated samples of two-dimensional materials such as graphene, hexagonal boron nitride (hBN), and transition metal dichalcogenides (TMDs), as well as multilayer heterostructures of such materials. Here we present detailed protocols for the experimental device fabrication of fragments and flakes of novel materials with micron-sized dimensions onto substrate and subsequent measurement in a commercial superconducting magnet, dry helium close-cycle cryostat magnetotransport system at temperatures down to 0.300 K and magnetic fields up to 12 T.

We describe the methodology of mechanical exfoliation and deposition of flakes of novel materials with micron-sized dimensions onto substrate, fabrication of experimental device structures for transport experimentation, and the magnetotransport measurement in a dry helium close-cycle cryostat at temperatures down to 0.300 K and magnetic fields up to 12 T.

Novel electronic materials are often produced for the first time by synthesis processes that yield bulk crystals (in contrast to single crystal thin film ...

Experimental Methods for Investigation of Shape Memory Based Elastocaloric Cooling Processes and Model Validation

Shape Memory Alloys (SMA) using elastocaloric cooling processes have the potential to be an environmentally friendly alternative to the conventional vapor compression based cooling process. Nickel-Titanium (Ni-Ti) based alloy systems, especially, show large elastocaloric effects. Furthermore, exhibit large latent heats which is a necessary material property for the development of an efficient solid-state based cooling process. A scientific test rig has been designed to investigate these processes and the elastocaloric effects in SMAs. The realized test rig enables independent control of an SMA&#39;s mechanical loading and unloading cycles, as well as conductive heat transfer between SMA cooling elements and a heat source/sink. The test rig is equipped with a comprehensive monitoring system capable of synchronized measurements of mechanical and thermal parameters. In addition to determining the process-dependent mechanical work, the system also enables measurement of thermal caloric aspects of the elastocaloric cooling effect through use of a high-performance infrared camera. This combination is of particular interest, because it allows illustrations of localization and rate effects &#8212; both important for efficient heat transfer from the medium to be cooled.
The work presented describes an experimental method to identify elastocaloric material properties in different materials and sample geometries. Furthermore, the test rig is used to investigate different cooling process variations. The introduced analysis methods enable a differentiated consideration of material, process and related boundary condition influences on the process efficiency. The comparison of the experimental data with the simulation results (of a thermomechanically coupled finite element model) allows for better understanding of the underlying physics of the elastocaloric effect. In addition, the experimental results, as well as the findings based on the simulation results, are used to improve the material properties.

Experimental methods for investigation of solid state cooling processes and characterization of elastocaloric material properties of Shape Memory Alloys (SMA) are presented. A custom-built test rig has been designed for controlling and comprehensive monitoring of elastocaloric cooling processes. Furthermore, it provides a validation platform for thermomechanically coupled modeling approaches.

Shape Memory Alloys (SMA) using elastocaloric cooling processes have the potential to be an environmentally friendly alternative to the conventional vapor ...

Emission Spectroscopic Boundary Layer Investigation during Ablative Material Testing in Plasmatron

Ablative Thermal Protection Systems (TPS) allowed the first humans to safely return to Earth from the moon and are still considered as the only solution for future high-speed reentry missions. But despite the advancements made since Apollo, heat flux prediction remains an imperfect science and engineers resort to safety factors to determine the TPS thickness. This goes at the expense of embarked payload, hampering, for example, sample return missions. 
Ground testing in plasma wind-tunnels is currently the only affordable possibility for both material qualification and validation of material response codes. The subsonic 1.2MW Inductively Coupled Plasmatron facility at the von Karman Institute for Fluid Dynamics is able to reproduce a wide range of reentry environments. This protocol describes a procedure for the study of the gas/surface interaction on ablative materials in high enthalpy flows and presents sample results of a non-pyrolyzing, ablating carbon fiber precursor. With this publication, the authors envisage the definition of a standard procedure, facilitating comparison with other laboratories and contributing to ongoing efforts to improve heat shield reliability and reduce design uncertainties.
The described core techniques are non-intrusive methods to track the material recession with a high-speed camera along with the chemistry in the reactive boundary layer, probed by emission spectroscopy. Although optical emission spectroscopy is limited to line-of-sight measurements and is further constrained to electronically excited atoms and molecules, its simplicity and broad applicability still make it the technique of choice for analysis of the reactive boundary layer. Recession of the ablating sample further requires that the distance of the measurement location with respect to the surface is known at all times during the experiment. Calibration of the optical system of the applied three spectrometers allowed quantitative comparison. At the fiber scale, results from a post-test microscopy analysis are presented.

Development of new ablative materials and their numerical modeling requires extensive experimental investigation. This protocol describes procedures for material response characterization in plasma flows with the core techniques being non-intrusive methods to track the material recession along with the chemistry in the reactive boundary layer by emission spectroscopy.

Ablative Thermal Protection Systems (TPS) allowed the first humans to safely return to Earth from the moon and are still considered as the only solution ...

Subsurface Defect Localization by Structured Heating Using Laser Projected Photothermal Thermography

The presented method is used to locate subsurface defects oriented perpendicularly to the surface. To achieve this, we create destructively interfering thermal wave fields that are disturbed by the defect. This effect is measured and used to locate the defect. We form the destructively interfering wave fields by using a modified projector. The original light engine of the projector is replaced with a fiber-coupled high-power diode laser. Its beam is shaped and aligned to the projector&#39;s spatial light modulator and optimized for optimal optical throughput and homogeneous projection by first characterizing the beam profile, and, second, correcting it mechanically and numerically. A high-performance infrared (IR) camera is set up according to the tight geometrical situation (including corrections of the geometrical image distortions) and the requirement to detect weak temperature oscillations at the sample surface. Data acquisition can be performed once a synchronization between the individual thermal wave field sources, the scanning stage, and the IR camera is established by using a dedicated experimental setup which needs to be tuned to the specific material being investigated. During data post-processing, the relevant information on the presence of a defect below the surface of the sample is extracted. It is retrieved from the oscillating part of the acquired thermal radiation coming from the so-called depletion line of the sample surface. The exact location of the defect is deduced from the analysis of the spatial-temporal shape of these oscillations in a final step. The method is reference-free and very sensitive to changes within the thermal wave field. So far, the method has been tested with steel samples but is applicable to different materials as well, in particular to temperature sensitive materials.

This method aims at locating vertical subsurface defects. Here, we couple a laser with a spatial light modulator and trigger its video input to heat a sample surface deterministically with two anti-phased modulated lines while acquiring highly resolved thermal images. The defect position is retrieved from evaluating thermal wave interference minima.

The presented method is used to locate subsurface defects oriented perpendicularly to the surface. To achieve this, we create destructively interfering ...