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Thin Film Oxide Electronics Laboratory. Equipment
IRE RAS. Research Activities Thin Film Oxide Electronics Laboratory IRE RAS - photo
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The HTSC group has an access to a set of technological equipment for thin film preparation and laboratory measurement system for low temperature electrical measurements.

Technological equipment

Lithography lineThe technological complex of the "Thin Film Oxide Electronics" Laboratory includes two clean rooms of the "1000" class, with a complete set of equipment for photolithography (spinner, oven, hot plate, mask aligner, chemical bench, de-ionized water source) in each clean room. The mask aligners are working in near UV light, providing line resolution of photolithography process down to 1 µm. Sencitive microscopes and profilometers allow immediate checks of the obtained thin film structure's geometry. High-vacuum deposition plant and microscopeModern thin film deposition plants of the "Leybold" (Germany) company provide high- and ultra-high oil-free vacuum and a possibility of thin film deposition using wide variety of deposition techniques: thermal evaporation, e-beam evaporation, DC- and RF-sputtering, reactive sputtering, etc. Plasma etching system, planarisation/polishing machine and automatized anodization system provide additional technological processes to implement a new thin film technology using many types of materials from metallic to ceramic and insulating. For example, the low-temperature superconducting circuit, produced using the "standard" niobium-aluminium-niobium multilayer structures implements the following materials: superconducting niobium layers, deposited using the RF- or DC-sputtering technique; insulating niobium oxide layers, prepared using the anodisation process; barrier/insulating aluminium oxide layers, prepared using RF-sputtering with a consequent oxydation at low oxygen pressure or using the anodisation process; silicon oxide or silicone dioxide insulating/planarisation coating, deposited using thermal evaporation or RF-sputtering; titanium or molibdenum metallization layer for resistor preparation, deposited using DC-sputtering; and gold or silver wiring metallisation layer, deposited using thermal evaporation or DC-sputtering. Typical niobium structure demands processing of 11-14 layers (deposition, photolithography, anodisation, etching, planarisation, lift-off and other processes). HTSC deposition systemThe technology of high-temperature superconductors is not that sophisticated yet, but multi-element composition, complicated crystal structure and high anisotropy of these materials present a real challenge to a technologist. The main problem is chemical compatibility of the high-temperature superconductor and metallisation/insulation/barrier materials. Deposition of the HTSC thin films is performed at high temperatures (about 800 °C), and usually demands relatively high oxygen pressures during deposition. Not many materials can withstand such a treatment, and the set of materials used together with the HTSC is limited almost to oxides group. We have rebuilt a Z-400 high-vacuum deposition system ("Leybold", Germany) to make possible deposition of oxide materials at high temperature and high oxygen pressure.Bonding system The self-made heater, controlled by an "Eurotherm" temperature controller provides heating up to 820 °C with accuracy of 1 °C. The oxygen flow to the chamber is set by a flowmeter while the rotary-vane pump is filled with the PFPE liquid, resistive to the chemically aggressive gases like oxygen. The deposition is usually done in argon/oxygen mixture to improve stability of the discharge and decrease negative-ion bombardment of the growing film surface. The pressure is controlled precisely with a capacitive vacuum meter. The deposition rate can be monitored with a quartz deposition rate sencor. The whole process is very complicated and accurate tuning of all deposition parameters is necessary. The area in the (discharge current - deposition temperature) co-ordinates, providing high properties of an YBa2Cu3Ox film, deposited on the CeO2 buffer layer is shown on the figure to the right. This area is limited but extensive ion bombardment (top border), underheating and overheating of the growing film (left-lower and right-upper borders). Similar graphs can be plotted for each combination of deposition parameters.

Electrical measurements equipment

CVC measurement systemAnother important part of HTSC group equipment is the low-temperature measurement systems for precise investigations of electrophysical properties of superconductive structures. Typically this kind of investigations is done by measurement of the current-voltage curves (CVC) of the sample. The computerized CVC measurement system is shown on the figure; the electronics block sets the current through the sample in accordance with the signal from the computer (Pentium-II PC) and amplifies the voltage from the sample. The amplified voltage is fed to the ADC and the digitized result is stored by the measurement program. This measurement system allows simultaneous passing of two calibrated currents through the sample circuits and amplification of two voltage signals; additional signals can be stored, like magnetic field in the sample vicinity, temperature readings, and differential resistance measured with a lock-in amplifier. The last two allow precise measurement of the R(T) curve and, thus, determination of the sample critical temperature and evaluation of structure perfectness. Other typical measurements, performed in this system, are Ic(H) - dependence of superconductor critical current on the external magnetic film, providing information of on the Josephson junction integrity; RD(V) - differential resistance dependence on voltage, revealing internal features of the Josephson junction and the HTSC material itself; and measurements of the CVC under external electromagnetic irradiation. These last ones are usually done using mm-wavelength and sub-mm-wavelength irradiation and are especially important for design and testing of Josephson effect detectors of electromagnetic radiation.
Zond for dipping a sample into a cooling liquidAll measurements are performed at temperatures below the room temperature; to achieve low temperature cooling liquids (liquid He and liquid nitrogen) are used. In the most simple case the sample is dipped into the liquid cooling agent in the transport dewar. Special dip-sticks are designed, providing precise measurement of temperature and magnetic field, feeding of the sample with current, measurement of the signal voltage, and waveguide for the external mm-wavelength irradiation. To avoid effects of air liquification, the air is pumped out of the dip stick, and the volume around the sample is filled with helium. The whole system is placed in a screening box, decreasing the external noise, especially the radio-frequency noise and external magnetic noise.
Sub-mm-wavelength generatorOur second measurement system allows studies of electrophysical properties of the HTSC samples under external sub-mm-wavelength irradiation. This kind of irradiation is fed into the cryostat with the sample using an optical line, consisting of set of lenses for microwave irradiation. The CVC measurements are done the same way, as in the first measurement system.

Meagurment system

 

 

 

 

 

 

Summarising, the "Thin Film Oxide Electronics" Laboratory, has an access to the following equipment:

  1. Technological complex for superconductive electronics device fabrication, including:
    • two clean rooms of class "1000";
    • high-vacuum plants for thin-film deposition of metal superconductors (niobium, aluminium, lead), normal metals and insulators using sputtering, e-beam and thermal evaporation techniques;
    • two sets of photolithography equipment (spinner, oven, chemical bench, etc.) with mask aligners with lithography resolution down to 1.0 mm;
    • set of measurement equipment for the lithography processes;
    • reactive plasma etching system, ion-beam etching facility.
  2. High-vacuum plant Z-400 ("Leybold AG", Germany) rebuilt for epitaxial growth of oxide films at high deposition temperatures:
    • high-Tc superconducting (YBa2Cu3Ox) thin films, and
    • growth of dielectric films like cerium and zirconium oxides
    with the heater which allows to obtain the temperature up to 850 °C in the oxygen atmosphere.
  3. Screening box and filter system for the precise DC measurements with low external noise. Several cryostats for measurements of the electrical transport properties at temperatures T = 3 - 300 K and magnetic fields B = 0 - 0.1 T. Measurement systems are controlled by data acquisition systems on the basis of PC and high-sensitive lock-in amplifiers PAR5301, PAR5210 ("EG&G", USA) and nano-voltmeters Keithley 2001, Keithley 1801, ("Keithley", USA).
  4. The mm-range electromagnetic radiation sources and measurement equipment for the frequencies 40, 100 and 300 GHz for studies of the microwave response of high-Tc Josephson junctions.