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History of NIST Quantum Voltage Standards


1980s

1981

Richard Kautz of NIST discovered why an array of 5,000 Josephson junctions shows no voltage steps at all—chaos theory. The junction response became chaotic when the external microwave frequency approached the resonance frequency of the Josephson junction. Kautz showed that stable, chaos-free voltages require a microwave frequency that is larger than the resonance frequency of the junction.

(Citation: R.L. Kautz, "The ac Josephson effect in hysteretic junctions: range and stability of phase lock," J. Appl. Phys. 52 (1981) 35283541)

 

1984

NIST and its German counterpart, Physikalisch-Technische Bundesanstalt (PTB), developed the first quantum voltage demonstration chip. The 1-volt chip has 1,474 Josephson junctions made of lead-indium-gold alloy electrodes. This array is not fully practical, because it often switches spontaneously between voltage levels, and the junctions cannot be thermally cycled, which occurs when the chip is taken in and out of liquid helium at 4 K.

(Artifact 1, Citation: J. Niemeyer, J.H. Hinken & R.L. Kautz, Appl. Phys. Lett. Vol. 45, August 1984, pp. 478-80)

 

1985

NIST made the world's first practical, stable and easy to use 1-volt standard, which had 1,484 junctions made of niobium and lead-indium-gold alloy superconducting electrodes and niobium oxide barriers. Each junction was 15 micrometers by 40 micrometers in size. The silicon chip was relatively large at 6.35 millimeters by 12.7 millimeters. This type of series-array microchip became the workhorse of voltage calibration around the world, with more than 50 systems operating in national, industrial, and military laboratories.

(Artifact 2, Citation: C.A. Hamilton, R.L. Kautz, R. L. Steiner, F. L. Lloyd, IEEE Elect. Dev. Lett. Vol. 6, Dec. 1985, pp. 623-625)

 

1989

NIST made the world's first 10-volt chip, with 14,184 junctions. Each junction had one niobium electrode, a niobium-oxide barrier, and lead-indium-gold as the second electrode. The original photograph of oscilloscope traces shows the first time in the world that a Josephson device (or any other device) generated a stable quantized voltage above 10 volts, as measured by Clark Hamilton on Jan. 6, 1988. The photo is a double exposure showing the current-volt loop and superimposed step (short vertical line at lower left) at about 10.8 volts.

(Artifact 3, Citation: C.A. Hamilton , F. L. Lloyd, K. Chieh, & W.C. Goeke, IEEE Trans. Inst. Meas. Vol. 38, April 1989, pp. 314-316)

 

1989

NIST researchers designed a waveguide holder and "spring-finger board" to deliver microwaves to the early volt standard chips. The chips are mounted in a brass holder. A pocket in the holder aligns the chip to a slot in the waveguide that delivers microwave power. The finger board presses down on the chip to hold it in place.

(Artifact 5)
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D. Sullivan an dR. Kautz with 1985 Stratton award

Don Sullivan and Richard Kautz with 1985 Samuel Wesley Stratton Award
credit: NIST
high resolution version

 

First quantum voltage demo chip

(1984) First quantum voltage demonstration chip
credit: Schmidt/NIST
high resolution version

 

first practical, stable, easy to use 1 volt standard chip

(1985) First practical, stable, and easy to use 1-volt standard chip
credit: Schmidt/NIST
high resolution version

 

Clark Hamilton wiht early volt standard apparatus

Clark Hamilton with early volt standard apparatus
credit: NIST
high resolution version

 

volt chip

First quantum 10-volt chip
credit: Schmidt/NIST
high resolution version

 

first quantum 10-volt chip with waveguide

(1989) First quantum 10-volt chip with waveguide
credit: Hamilton/NIST
high resolution version

 

Original photo of oascilloscope traces

(1989) Original photo of oscilloscope traces (double exposure)
credit: Hamilton/NIST
high resolution version

 

Original weaveguide showing pressed-indium connections for 10-volt standards

(1989) Original chip holder and waveguide that delivered microwave power to early 10-volt standard chips
credit: Hamilton and Benz/NIST
high resolution version