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TitleOptical cavity integrated surface ion trap for enhanced light collection
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                            University of New Mexico
UNM Digital Repository
	2-1-2016
Optical cavity integrated surface ion trap for enhanced light collection
	Francisco Martin Benito
		Recommended Citation
tmp.1471632845.pdf.aI64W
                        
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University of New Mexico
UNM Digital Repository

Nanoscience and Microsystems ETDs Engineering ETDs

2-1-2016

Optical cavity integrated surface ion trap for
enhanced light collection
Francisco Martin Benito

Follow this and additional works at: https://digitalrepository.unm.edu/nsms_etds

This Dissertation is brought to you for free and open access by the Engineering ETDs at UNM Digital Repository. It has been accepted for inclusion in
Nanoscience and Microsystems ETDs by an authorized administrator of UNM Digital Repository. For more information, please contact
[email protected]

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Francisco M. Benito

Candidate

Nanoscience and Microsystems

Department

This dissertation is approved, and it is acceptable in quality and form for publication: Approved

by the Dissertation Committee:

Dr. Zayd C. Leseman, Chair

Dr. Daniel L. Stick, Co-Chair

Dr. Mani Hossein-Zadeh, Member

Dr. Peter L. Maunz, Member

Dr. Grant W. Biedermann, Member

Page 61

Chapter 4. Experimental cavity

RoC 5mm

1mm

Figure 4.10: Curved mirror characterization

46

Page 62

Chapter 4. Experimental cavity

RoC 5mm

L=0.92 mm

Figure 4.11: Curved and flat silicon mirror

47

Page 122

References

[60] MG Raizen, JM Gilligan, JC Bergquist, WM Itano, and DJ Wineland. Ionic
crystals in a linear paul trap. Physical Review A, 45(9):6493, 1992.

[61] Paul Aveling Redhead, John Peter Hobson, and Ernest Victor Kornelsen. Phys-
ical basis of ultrahigh vacuum. 1968.

[62] L Ricci, M Weidemüller, T Esslinger, A Hemmerich, C Zimmermann, V Vuletic,
W König, and Th W Hänsch. A compact grating-stabilized diode laser system
for atomic physics. Optics Communications, 117(5):541–549, 1995.

[63] Bahaa EA Saleh, Malvin Carl Teich, and Bahaa E Saleh. Fundamentals of
photonics, volume 22. Wiley New York, 1991.

[64] Erwin Schrödinger. Discussion of probability relations between separated sys-
tems. In Mathematical Proceedings of the Cambridge Philosophical Society, vol-
ume 31, pages 555–563. Cambridge Univ Press, 1935.

[65] Benjamin Schumacher. Quantum coding. Physical Review A, 51(4):2738, 1995.

[66] Signe Seidelin, John Chiaverini, Rainer Reichle, JJ Bollinger, Didi Leibfried, Joe
Britton, JH Wesenberg, RB Blakestad, RJ Epstein, DB Hume, et al. Microfab-
ricated surface-electrode ion trap for scalable quantum information processing.
Physical review letters, 96(25):253003, 2006.

[67] A. E. Siegman. Lasers. University Science Books, 1986.

[68] JD Siverns, LR Simkins, S Weidt, and WK Hensinger. On the application of
radio frequency voltages to ion traps via helical resonators. Applied Physics B,
107(4):921–934, 2012.

[69] Jonathan David Sterk. Enhanced light collection from single trapped ions. PhD
thesis, University of Maryland, 2011.

[70] D Stick, KM Fortier, R Haltli, C Highstrete, DL Moehring, C Tigges, and
MG Blain. Demonstration of a microfabricated surface electrode ion trap. arXiv
preprint arXiv:1008.0990, 2010.

[71] Dan Stick, WK Hensinger, Steven Olmschenk, MJ Madsen, Keith Schwab, and
Chris Monroe. Ion trap in a semiconductor chip. Nature Physics, 2(1):36–39,
2006.

[72] Ihab El-Kady Hayden McGuinness Daniel Stick Susan Clark, Kevin M. Fortier
and Charles Reinke. Frequency translation to demonstrate a hybrid quantum
architecture. Technical report, Sandia National Laboratories, 2014.

107

Page 123

References

[73] Boyan Tabakov, Francisco Benito, Matthew Blain, Craig R Clark, Susan Clark,
Raymond A Haltli, Peter Maunz, Jonathan D Sterk, Chris Tigges, and Daniel
Stick. Assembling a ring-shaped crystal in a microfabricated surface ion trap.
arXiv preprint arXiv:1501.06554, 2015.

[74] Smith. Arlee V. Design for wavelength converters for (397 nm to 702 nm), (397
nm to 775 nm). Technical report, AS Photonics, 2012.

[75] Carl E Wieman and Leo Hollberg. Using diode lasers for atomic physics. Review
of Scientific Instruments, 62(1):1–20, 1991.

[76] David J Wineland, C Monroe, WM Itano, D Leibfried, BE King, and
DM Meekhof. Experimental issues in coherent quantum-state manipulation of
trapped atomic ions. arXiv preprint quant-ph/9710025, 1997.

[77] William K Wootters and Wojciech H Zurek. A single quantum cannot be cloned.
Nature, 299(5886):802–803, 1982.

[78] Anton Zeilinger. Dance of the photons: From Einstein to quantum teleportation.
Macmillan, 2010.

[79] WZ Zhao, JE Simsarian, LA Orozco, and GD Sprouse. A computer-based
digital feedback control of frequency drift of multiple lasers. Review of scientific
instruments, 69(11):3737–3740, 1998.

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