SU-8 Layer Research Articles

Cost-Effective Fabrication of Polydimethylsiloxane (PDMS) Microfluidics for Point-of-Care Application

Microfluidics fabrication pertains to the construction of small-scale devices and systems that manipulate and control small volumes of fluids. This process involves precise engineering and manufacturing procedures aimed at designing and producing these devices, which find applications in healthcare, environmental monitoring, and chemical analysis. The present study showcases an inexpensive approach to fabricate microfluidics channels using PDMS biopolymer and soft lithography technique to achieve laminar fluid flow. Initially, a robust and adhesive mold was created by fabricating a master template using several layers of SU-8 5 and SU-8 2015 negative photoresists. Subsequently, PDMS microfluidics channels were replicated and sealed onto a glass substrate through plasma bonding treatment. High-power microscopy images and profilometer analyses demonstrated successful fabrication with minimal deviation from the initial designs and the fabricated devices (less than 0.07 mm, less than 0.6°). Both the SU-8 master template and PDMS replicate displayed average microchannel height values and surface roughness of 100 μm and 0.26 μm or lower, respectively. Additionally, the fluid test confirmed laminar flow without any leakage post plasma oxidation, indicating the completion of an efficient and cost-effective fabrication process.

Microfabricated free standing, tuneable, porous microfilters from an epoxy based photoresist for effective bioseparation.

SU-8 is an epoxy-based, biocompatible thermosetting polymer, which has been utilized mainly to fabricate biomedical devices and scaffolds. In this study, thin, single-layered, freestanding tuneable porous SU-8 membranes were microfabricated and surface hydrophilized for efficient bioseparation. Unlike the previous thicker membranes of 200-300 μm, these thin SU-8 membranes of 50-60 μm thickness and pores with 6-10 μm diameter were fabricated and tested for blood-plasma separation, without any additional support structure. The method is based on making a patterned SU-8 layer by electrospin coating and UV lithography on a sacrificial polyethylene terephthalate (PET) sheet attached to a silicon wafer. Poor adhesion between PET and SU-8 aid in the convenient release of the thin porous membranes with uniform pore formation. The single-layered self-supporting membranes were strong, safe, sterilizable, reusable, and suitable for plasma separation and postfermentation broth enrichment.

Back Gate Bias Influence on BESOI ISFET Sensitivity

The application of Field Effect Transistors (FETs) to sensors and biosensors allows a mass production, low cost, small size, fast response and, also, the possibility of integrating the device and conditioning signal circuit in the same integrated circuit (IC). The Ion Sensitive Field Effect Transistor (ISFET), invented in 1970 by Piet Bergveld (1), is a device similar to the conventional Metal-Oxide-Semiconductor Field Effect Transistor (MOSFET), except that the metal gate is replaced by an inert electrode/pseudo electrode and a sample solution, in order to expose the gate oxide layer to ions present in the solution. The solution charges change the electrical potential in the gate oxide surface and, consequently, the device threshold voltage changes as a function of the ion concentration in the sample solution, being used as a pH sensor. Thus, the ISFET is a very promising device to Point-of-Care (POC) monitoring, such as COVID-19 control (2) and for continuous in vivo monitoring ion activity in biological processes (3)-(6).The BESOI (Back Enhanced Silicon-On-Insulator) MOSFET is a device patented in 2015 by João Antonio Martino and Ricardo Cardoso Rangel (7). This device is easy to fabricate and low cost. In the last years, the research using this device as a sensor/biosensor has been done (8)-(14). This paper presents, for the first time, the BESOI MOSFET working as an Ion Sensitive Field Effect Transistor (ISFET): the BESOI ISFET. Therefore, the focus of this work is to study the device electrical behavior influenced for pH standard solutions.The BESOI ISFET was fabricated at Integrated System Laboratory (LSI) from University of Sao Paulo (USP), Brazil. It is a planar device made on a SOI (Silicon-On-Insulator) wafer with three conventional photolithography steps, in an analogous way to previous work (15) and one more photolithography step to create microchannel and microreservoirs with SU-8 (16) layer to contain the sample solution. The wafer has no doping process (there is only the natural wafer doping of 1015 cm-3). The silicon channel layer and the gate oxide (SiO2) thicknesses are 10 nm and 25 nm, respectively. The buried oxide layer thickness is 200 nm. The drain and source contacts are fabricated with nickel and the contact pads using aluminum. The Figure 1 presents the final device layout and the Figure 2 shows the device schematic drawn.Differently from a conventional ISFET, where the drain current flows at the front interface, in the BESOI ISFET the drain current flows at the back interface. As the BESOI ISFET is a non-intentionally doped device, the free conduction charge layer is formed by biasing the Back Gate electrode (VGB). When a positive enough VGB is applied, electrons are attracted and accumulated at the back interface, and therefore, current flows from source to drain when VDS (Drain bias) is applied. A Platinum (Pt) pseudo-electrode is used to apply front-gate voltage (VGF) to the sample solution.The experimental drain current (IDS) as a function of the front-gate voltage (VGF), for 25 V applied at the back-gate (VGB), is presented in Figure 3.A, which is possible to observe that the neutral pH (pH7) curve stayed between the acid pH (pH4) curve, in the left, and alkaline pH (pH10) curve, in the right. This result shows that the threshold voltage (VTH) is lower for acid pH and higher for alkaline pH, what is compatible with the conventional ISFET results present in the literature (17). To corroborate the experimental measurement result, the device simulation was made with TCAD-Sentaurus (18), based in the paper (19). Figure 3.B shows the same trend for the simulated device with pH solution for any VGB value.In Figure 4, the threshold voltage was analyzed as a function of the pH for different VGB values. The VTH increases (becomes more positive) for alkaline pH values, regardless of the VGB applied. However, the VTH variation in the pH range, between pH4 and pH10, is different for different VGB values. With higher VGB applied, higher is the VTH variation. In Figure 5 Is possible to see clearly that the sensitivity (ΔVTH /ΔpH) increases with the VGB increase probably due to the small influence of the series resistance. In another hand, the acquired sensitivity values for VGB higher than 15 V in this work (about 25-33 mV/pH, approximately), is compatible with results present in the literature for conventional ISFETs with silicon dioxide (SiO2) for gate insulator (20). Figure 1

Origami-Inspired Fabrication of High-Performance Wafer-Level Packaged Three-Dimensional Radio-Frequency Inductors

Planar radio-frequency (RF) on-chip inductors suffer from large electromagnetic losses, stemming from the low resistivity silicon substrate. Though it is well-known that 3-dimensional (3D) MEMS-based RF inductors offer significant performance enhancement by reducing the substrate proximity effects, they are prone to mechanical failures and often come without any appropriate packaging, leading to reliability issues. Herein, we report an approach to fabricate highly robust packaged 3D RF inductors, while relying on the concept of stress-induced self-assembly. By leveraging the large residual stresses in evaporated chromium thin films at low thicknesses (below 50 nm), we assemble the planar copper coils coated with chromium nano-layers into out-of-plane folded RF inductors, directly improving their <inline-formula xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink"> <tex-math notation="LaTeX">$Q$</tex-math> </inline-formula> -factor. Through measurements, we show more than three-fold ( <inline-formula xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink"> <tex-math notation="LaTeX">$\sim$</tex-math> </inline-formula> 300%) improvement in the inductor <inline-formula xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink"> <tex-math notation="LaTeX">$Q$</tex-math> </inline-formula> -factor after the bending. Considering the inherent fragility of suspended inductors, we then add a dedicated wafer-level polymer packaging to our inductors, to improve their mechanical robustness. Specifically, we coat a thick SU-8 layer using a quasi-static volumetric dispensing process, to embed the inductors without deforming them. Upon baking, the polymer layer solidifies, making the buried inductors extremely rigid. We show that though our inductors have <inline-formula xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink"> <tex-math notation="LaTeX">$Q$</tex-math> </inline-formula> -factors similar to existing MEMS inductors, their low design complexity and high strength gained via polymer packaging make them stand out among the others. This packaging technique essentially paves the way for the widespread commercialization of suspended inductors, which has been hindered in the past by their poor mechanical reliability. 2023-0018

Square-package arrays for efficient trapping of terahertz waves

In this paper, a broadband metamaterial absorber consisting of the doped silicon substrate and the square array of doped silicon covered by a SU-8 layer is presented. The target structure achieves an average absorption of 94.42% in the studied frequency range (0.5–8 THz). In particular, the structure exceeds 90% absorption in the frequency range of 1.44–8 THz, which is a significant increase in bandwidth relative to reported devices of the same type. Next, the near-perfect absorption of the target structure is verified by the impedance matching principle. Furthermore, through the analysis of the electric field distribution inside the structure, the physical mechanism of its broadband absorption is investigated and explained. Finally, the impact of fluctuations in the incident angle, polarization angle, and structural parameters on the absorption efficiency is examined at length. The analysis shows that the structure has characteristics, such as polarization insensitivity, wide-angle absorption, and good process tolerance. The proposed structure is advantageous for applications in THz shielding, cloaking, sensing, and energy harvesting.

Self-aligned multi-layer X-ray absorption grating using large-area fabrication methods for X-ray phase-contrast imaging

X-ray phase-contrast (XPCi) imaging methods are an emerging medical imaging approach that provide significantly better soft tissue contrast and could function as a viable extension to conventional X-ray, CT, and even some MRI. Absorption gratings play a central role in grating-based XPCi systems, especially because they enable the acquisition of three images in a single exposure: transmission, refraction, and dark-field. An impediment to commercial development and adoption of XPCi imaging systems is the lack of large area, high aspect ratio absorption gratings. Grating technology development, primarily due to technological limitations, has lagged system development and today prevents the scaling up of XPCi system into a footprint and price point acceptable to the medical market. In this work, we report on a self-aligned multi-layer grating fabrication process that can enable large-area X-ray absorption gratings with micron-scale feature sizes. We leverage large-area fabrication techniques commonly employed by the thin-film transistor (TFT) display industry. Conventional ITO-on-glass substrates are used with a patterned film of Cr/Au/Cr that serves as a self-aligned lithography mask for backside exposure. Commonly available SU-8 photoresist is patterned using the backside exposure mask followed by an electroplating step to fill the gaps in the SU-8 with X-ray attenuating material. Consequently, the electroplated patterned material acts as a self-aligned photomask for subsequent SU-8 layer patterning and so forth. The repeatability of the reported process makes it suitable for achieving higher aspect ratio structures and is advantageous over previously reported X-ray LIGA approaches. A prototype three-layer grating, with a thickness of around 40,upmu text{m}, having a visibility of 0.28 at 60,text{kV}_p with a 70,text{mm}times 70,text{mm} active area was fabricated on a 4-inch glass substrate and demonstrated by modifying a commercially available 3D propagation-based XPCi Microscope. The scalable and cost-effective approach to build larger area X-ray gratings reported in this work can help expedite the commercial development and adoption of previously reported Talbot-Lau, speckle-tracking, as well as coded-aperture XPCi systems for large-area clinical and industrial applications.

Hybrid and heterogeneous photonic integrated near-infrared InGaAs/InAlAs single-photon avalanche diode

We have demonstrated the integrated indium gallium arsenide/indium aluminum arsenide (InGaAs/InAlAs) single-photon avalanche diodes (SPAD) with silicon (Si) waveguides and grating couplers on the Silicon-on-insulator substrate. A vertical coupling scheme is adopted which allows the use of a thick bonding interlayer for high yield. The epoxy ‘SU-8’ is selected to be the adhesion layer with a low transmission loss, low volumetric shrinkage, and low curing temperature. In addition, both hybrid and heterogeneous integration schemes are realized which are compatible with the current multi-project wafer process. Extensive performance characterization is carried out while the results are compared. Our hybrid integrated SPAD exhibits high photon detection efficiency (PDE) of ∼21% and a relatively low dark count rate (DCR) of 8.6 × 105 Hz, which are among the best performance reported for InGaAs/InAlAs SPADs while the heterogeneous integrated SPAD shows a decent PDE of 6% with a DCR of 2 × 107 Hz. Combined with the inherent wide applicability of the bonding using the SU-8 layer, this photonic integration provides a promising solution for large-scale quantum information with various material systems.

A novel approach to design and fabricate an electrothermal microgripper for cell manipulation

Microgrippers are used in cell manipulation, micro-assembly, and material characterization. However, rarely a systematic approach is presented for microgripper design. The current research presents a methodology for single-cell manipulation design and fabricating a MEMS electrothermal microgripper. The result is a list of constraints required for microgripper design. The jaw thickness is defined by simulating oocyte gripping and injecting quantitatively; a genuine approach is presented here. Due to the long list of extracted constraints, a genetic algorithm (GA) is employed to optimize the design to satisfy all constraints. To do so, the required analytical models are developed to be used in the GA. UV- LIGA is employed to fabricate the device with nickel as the structural layer and copper as the sacrificial layer. The microgripper has a compliant structure with a thin layer of titanium and SU8 coated on jaws. The simulation and experimental results shows that the designed structure provides the jaw displacement of 52 µm at the voltage of 0.172 V and a maximum temperature of 75 ºC, with activation and cooling time of 0.3 s (jaw opening and closing). The procedure developed in this research is a systematic approach and can be adopted to design other types of microgrippers for different applications.

A MEMS Micro Force Sensor Based on A Laterally Movable Gate Field-Effect Transistor (LMGFET) with A Novel Decoupling Sandwich Structure

This paper presents the development of a novel micro force sensor based on a laterally movable gate field-effect transistor (LMGFET). A precise electrical model is proposed for the performance evaluation of small-scale LMGFET devices and exhibits improved accuracy in comparison with previous models. A novel sandwich structure consisting of a gold cross-axis decoupling gate array layer and two soft photoresistive SU-8 layers is utilized. With the proposed dual-differential sensing configuration, the output current of the LMGFET lateral operation under vertical interference is largely eliminated, and the relative output error of the proposed sensor decreases from 4.53% (traditional differential configuration) to 0.01%. A practicable fabrication process is also developed and simulated for the proposed sensor. The proposed LMGFET-based force sensor exhibits a sensitivity of 4.65 µA·nN−1, which is comparable with vertically movable gate field-effect transistor (VMGFET) devices, but has an improved nonlinearity of 0.78% and a larger measurement range of ±5.10 µN. These analyses provide a comprehensive design optimization of the electrical and structural parameters of LMGFET devices and demonstrate the proposed sensor’s excellent force-sensing potential for biomedical micromanipulation applications.

W-Band 4th Order Waveguide Filter Based on Double Layer SU8 Microfabrication.

This paper investigates the fabrication accuracy of the W-band SU-8 photoresist micromachined 4th order waveguide bandpass filters (BPF). The designed filter based on cylindrical resonators is excited in TM010 mode. It is ideally suitable for the layered SU-8 micromachining process as the height of the resonator is much smaller than one wavelength, the electromagnetic fields remain unchanged in the thickness direction. The filter is composed of three silver-coated SU-8 layers based on a double-layer overlay process. Excellent manufacturing tolerances can be controlled within 4 μm in the thickness direction, around 10 μm in double-layer stacking accuracy, and an average of 1° in vertical angle deviation. Various challenges encountered in the SU-8 process are investigated while corresponding general solutions are proposed for machining high-precision devices. The measured results show a return loss of 12.4 dB and a minimum insertion loss of 0.8 dB, which are in agreement with the simulated one. Stress and deformation analysis are also conducted to confirm the maximum pressure that the filter can withstand and maintain good transmission performance.

Optically switchable ultra-broadband terahertz perfect absorption in doped superlattice photonic-crystal silicon

We propose an optically switchable ultra-broadband terahertz (THz) perfect absorber based on doped superlattice photonic-crystal silicon. The structure consists of a superlattice photonic crystal silicon slab capped by a SU-8 layer with no metal reflector. It achieves ultra-broadband perfect absorption due to the coupled cavity modes of superposed lattices with two different cavity radii and the enhanced diffraction assisted by the top SU-8 layer. Switchable absorption is realized by changing the carrier concentration of doped silicon controlled by pump beam. Simulation shows that proposed structure exhibits polarization-insensitive and wide-angle absorption with efficiency larger than 90% within 1.03 to 5 THz ultra-broadband, with modulation depth larger than 60% within bandwidth more than 1 THz. The all-dielectric structure uncommonly integrates optical switching, ultra-broadband absorption, polarization, and incident angle insensitivity, which may find potential applications in dynamic THz devices.

Analysis of dielectric constant behavior of thermally treated SU-8 polymer up to 18 GHz

Su-8 polymer has excellent potential for application in process manufacturing. This paper presents the effects of thermal stress on the electromagnetic properties of SU-8 polymer, showing the frequency-dependent microwave response of the material. The procedure follows the international standard method for assessing the quality of components and devices for space qualification as thermal stress simulates the aging process. The polymer has been used as a base layer to fabricate passive devices in the coplanar waveguide (CPW) configuration. Resonating structures and delay lines, with different sizes, have been manufactured on a SU-8 layer spun on a high resistivity silicon wafer. The material's dielectric constant has been calculated by measuring the microwave response of the devices before and after the thermal processes. We have recorded data in a broadband range, from 2 GHz to 18 GHz, and the conclusive comparison allows us to identify a frequency dependence of the electromagnetic performances of SU-8 polymer and confirms the possibility to use it for medium- and long-term microwave space applications. Specifically, minor changes of the electrical matching have been recorded in the Ku-band, from 12 GHz to 18 GHz, making the polymer reliable for current space communications.

Determination of thermal conductivity, thermal diffusivity and specific heat capacity of porous silicon thin films using the 3ω method

Here the thermal transport properties of low thermal conductivity porous silicon thin films attached to high thermal conductivity silicon substrates are studied using the 3ω method implemented over the 100 Hz to 33 kHz frequency range. The thermal conductivity and thermal diffusivity of the films are extracted using temperature impedance monitoring of electrical contacts deposited on films, combined with an extended-frequency, multi-layer thermal model. From the extracted thermal conductivity and diffusivity of the films, the heat capacity could be determined. Validation of the approach is performed using the known properties of thick substrate glass and SU-8 layers spun on silicon substrates, the latter ranging in thickness from 1.35 to 12.5 µm. The technique was then applied to porous silicon films with porosities ranging from 45% to 77%. The extracted thermal properties for as-fabricated films show a reduction of thermal conductivity and diffusivity from 1.7 to 0.15 W/mK and 1.9 to 0.2 mm2/s, respectively as the porosity increases. After passivation by annealing in nitrogen and at 600 °C, the same films exhibited higher values of thermal conductivity and diffusivity ranging from 2.7 to 0.7 W/mK and 2.5 to 0.65 mm2/s. The ability to extract both thermal conductivity and thermal diffusivity for these films removes the need to make assumptions around specific heat capacity, commonly made during analysis of porous media. These results show for the first time a monotonic increase in specific heat capacity of porous silicon films as a function of porosity.

Microfabricated porous SU-8 membranes as innervation interfaces for hiPSC-neurons in microfluidic devices

In this study, we developed microfabricated porous membranes aimed at facilitating innervation in 3D cell culture models. The aim of the paper is to introduce a fabrication method for porous membranes with adjustable size, shape and location of the pores without obstructing imaging or the connectivity of the cells. The method is based on making a patterned SU-8 layer on a sacrificial aluminium layer by UV lithography and releasing it with etching. With the proposed method, we were able to produce single-layer self-supporting membranes that were used as interfaces in compartmentalized microfluidic devices. The functionality of the membranes and their cytocompatibility were tested by culturing human pluripotent stem cell (hPSC)-derived neurons on their surfaces. In vitro experiments demonstrated that a dense neural network develops on top of the proposed membranes within a week. Neurites were able to migrate through the pores to the bottom side of the membranes. We achieved partial, but still significant, axonal isolation. The results of this study will pave the way for the development of optimized innervated tissue models by using the combination of porous SU-8 membrane substrates, microelectrode arrays and hPSC-derived neurons in compartmentalized cell cultivation devices.

SU-8 processing improvement and simulating studies for a Micromegas detector fabrication

This paper reports the manufacturing methodology to produce an electron multiplier, a Micromegas device, integrated onto a micro-pixel readout anode using a Silicon wafer as a holder. It describes the improvement in the processing of the insulating grid material SU-8 and electrical tests with the device. For the latter purpose, simulations with Garfield++ are carried out to predict the detector response for different gas mixtures. The Micromegas detector sandwich proposed in this work presents a series of problems, which we have addressed and discussed within this paper. The temperature control throughout the processing of SU-8 is extremely important, to be able to develop it. When developing the final SU-8 layer, we have used an extra photoresist, which combined with the SU-8, resulted in a much-improved shape of the Micromegas SU-8 hole-grid. Electrical testes are performed in order to verify the signals produced by a 55Fe radioactive source. A gas gain about 1,3 × 102, using Ar/C2H6 (75/25) mixture, is achieved for the prototype manufactured.

Guided Mode Resonance in a Low-Index Waveguide Layer

In this paper, we show that the guided mode resonance can exist in a low-index waveguide layer on top of a high-index substrate. With the help of the interaction of diffraction from a metal grating and total internal reflection effects, we verify that the guided mode can be supported in the low-index SU8 layer on a high-index substrate. Simulation and experiment show the resonant wavelength can be simply manipulated by controlling the geometrical parameters of the metal grating and waveguide layer. This structure extends the possibilities of guided-mode resonance to a broader class of functional materials and may boost its use in applications such as field enhancement, sensing and display.

The Effects of a Coated Material Layer on High-Overtone Bulk Acoustic Resonator and its Possible Applications.

This article describes the characterization and analysis of the effects an additional polymer layer has on a high-overtone bulk acoustic wave resonator based on Ba0.5Sr0.5TiO3 (BSTO) thin film by studying its spectral information. From both the simulation (numerical model) and experimental results of the resonator with and without coating, significant difference of both cases is evident in the spacing of the parallel resonance frequencies (SPRFs), effective coupling coefficient ( [Formula: see text]), and quality factor distribution of the resonator. The acoustic velocity of the coated material (SU-8) is calculated from the new periodicity introduced in the SPRF distribution. The SPRF distribution of the SU-8-coated resonator decreases overall as expected due to the additional layer introduced but sharply increases in regions defined by the thickness and acoustic velocity of the SU-8 layer. The mechanical loss of the added layer has significant effect on the parameters of the resonator. The study reveals that this method of characterization can be used to approximate the mechanical loss of materials such as polymers or polymer composites. The simulation with finite-element method agrees with the experimental result.

Design and verification of a tunable metamaterial and its sensing application

In this study, the authors present a single-band tunable metamaterial absorber in the 3.00–6.00 THz region. This absorption peak (90.00% amplitude) is excited by the cavity resonance at the resonance frequency of 4.55 THz. The cavity resonance mode is achieved in the spacer cavity formed by the metal/strontium titanate (STO)/SU-8 photoresist (SU-8)/STO/metal layers. The effect of structural parameters on this absorption peak is measured in two groups of experiments. As the diameter of holes array D increases, the cavity resonance peak is enhanced to 94.00% and shifted to 4.79 THz. However, for the increase in the thickness of the SU-8 layer T3, this peak is increased to 98.00% and moved to 3.88 THz. To verify the dual detection functions, two sets of experiments are carried out. In the third set of experiments, this absorption peak is increased to 99.80% and shifted to 5.60 THz with the increasing environmental temperature. In the fourth set of experiments, samples are covered by three liquids, and both the absorption amplitude and the resonance frequency are reduced. This tunable metamaterial absorber shows possibilities for applications in environmental temperature sensing and liquid sensing.

A rapid technique to integrate micro-components on released MEMS dies using SU-8

This technical note reports a rapid technique to post-process and assemble micro-components onto dies including released movable microstructures. The method is applied to microelectromechanical systems (MEMS) chips that were fabricated using a commercial process, PolyMUMPs from MEMSCAP. It allows the assembly of a micro-polyhedron over released micromotors and ensures that the micromotors remain fully functional. The micro-polyhedrons are fabricated using laser ablation and are spin coated with a thin layer of SU-8, acting as a bonding layer. Then, they are bonded to chips that are placed on a 3D integration platform with a navigating mask, which protects the released structure during the subsequent assembly steps. The resulting micro-polyhedron-integrated-micromotors were tested and found to rotate similarly to devices without micro-polyhedrons, demonstrating that the developed procedure can be applied for post-release 3D integration of MEMS without significantly affecting the mechanical performance of the devices.

Realisation of a sub-wavelength dimple using a 193 nm wavelength photonic nano jet

There are many areas of research that benefit from tight focussing of light. We report experimental and computational results of a laser irradiated silica microsphere, 1 μm diameter localised on an SU-8 substrate. A single pulse from an ArF excimer laser (λ = 193 nm) was used to generate a Photonic Nano Jet (PNJ). Subsequently the PNJ was used as a processing tool to produce a dimple cavity in the supporting SU-8 layer. Atomic Force Microscopy (AFM) was employed to determine dimple geometry. Measurements revealed a diameter of 150 ± 10 nm at full-width-half-maximum and a depth of 180 ± 10 nm. Finite Difference Time Domain (FDTD) simulations were carried out to visualise the propagation of 193 nm radiation through a microsphere. Experimental measurements and simulations were in close agreement confirming that the electromagnetic radiation is tightly focussed by the microsphere. Finite Element Method (FEM) simulations were also carried out to calculate the laser induced temperature rise of SU-8 in the region beneath the microsphere. FEM simulations predicted a temperature of 775 K which is above the boiling point of SU-8 (480 K). We briefly discuss the ejection mechanism of the microsphere in terms of the increase in temperature of the underlying SU-8.