Counting Spins with a New Spin Echo Double Resonance

Tom S. Cull; J. M. Joers; Terry Gullion; R. E. Norberg; Mark S. Conradi

doi:10.1006/jmre.1998.1478

Counting Spins with a New Spin Echo Double Resonance

Tom S. Cull, J. M. Joers, Terry Gullion, R. E. Norberg, Mark S. Conradi

Radiology

Research output: Contribution to journal › Article › peer-review

12 Scopus citations

Abstract

In traditional spin echo double resonance (SEDOR), the echo amplitude M is decreased when the observed spins S are flipped by π together with the π refocusing pulse on the observed spins I; the dependence on τ is then determined. In the new version of SEDOR, the echo amplitude is measured as a function of the S spin flip angle θ at a constant pulse spacing τ. The analysis is simple and powerful for long τ, where the strong collision limit applies. There, the variation of M with θ can be fit, yielding the number n of spins S to which each spin I is coupled. Data from amorphous silicon with ¹H and ²D show the described effect. A MAS version of the new method is used on multiply labeled alanine and urea, with results in good agreement with the predictions for n = 2, as expected. By Fourier transforming M with respect to the flip angle θ, a stick spectrum results; the largest numbered non-vanishing stick yields the number n of spins S coupled to each spin I. Simulations are presented for an n = 2 system. The present technique is compared to the multiple-quantum spin-counting method.

Original language	English (US)
Pages (from-to)	352-357
Number of pages	6
Journal	Journal of Magnetic Resonance
Volume	133
Issue number	2
DOIs	https://doi.org/10.1006/jmre.1998.1478
State	Published - Aug 1998

Bibliographical note

Funding Information:
The authors thank Ken Sakaie for helpful conversations. The mathematical assistance of W. H. Dickhoff is appreciated. Financial assistance through NSF grant DMR-9705080 (MSC), NSF grant CHE-9796188 (TG and JMJ), and grant DMR-9305344 (REN and TSC) is gratefully acknowledged. The work was partially supported (TG and JMJ) through a grant of the Petroleum Research Fund, administered by the American Chemical Society. TSC gratefully acknowledges partial support as a Sirovich Fellow.

Keywords

Double resonance
SEDOR
Solid-state NMR
Spin echo
Unlike spins

Access

10.1006/jmre.1998.1478

OpenUrl availability

Full text

Cite this

@article{db1c3c29da174d4b975a838584728724,

title = "Counting Spins with a New Spin Echo Double Resonance",

abstract = "In traditional spin echo double resonance (SEDOR), the echo amplitude M is decreased when the observed spins S are flipped by π together with the π refocusing pulse on the observed spins I; the dependence on τ is then determined. In the new version of SEDOR, the echo amplitude is measured as a function of the S spin flip angle θ at a constant pulse spacing τ. The analysis is simple and powerful for long τ, where the strong collision limit applies. There, the variation of M with θ can be fit, yielding the number n of spins S to which each spin I is coupled. Data from amorphous silicon with 1H and 2D show the described effect. A MAS version of the new method is used on multiply labeled alanine and urea, with results in good agreement with the predictions for n = 2, as expected. By Fourier transforming M with respect to the flip angle θ, a stick spectrum results; the largest numbered non-vanishing stick yields the number n of spins S coupled to each spin I. Simulations are presented for an n = 2 system. The present technique is compared to the multiple-quantum spin-counting method.",

keywords = "Double resonance, SEDOR, Solid-state NMR, Spin echo, Unlike spins",

author = "Cull, {Tom S.} and Joers, {J. M.} and Terry Gullion and Norberg, {R. E.} and Conradi, {Mark S.}",

note = "Funding Information: The authors thank Ken Sakaie for helpful conversations. The mathematical assistance of W. H. Dickhoff is appreciated. Financial assistance through NSF grant DMR-9705080 (MSC), NSF grant CHE-9796188 (TG and JMJ), and grant DMR-9305344 (REN and TSC) is gratefully acknowledged. The work was partially supported (TG and JMJ) through a grant of the Petroleum Research Fund, administered by the American Chemical Society. TSC gratefully acknowledges partial support as a Sirovich Fellow.",

year = "1998",

month = aug,

doi = "10.1006/jmre.1998.1478",

language = "English (US)",

volume = "133",

pages = "352--357",

journal = "Journal of Magnetic Resonance",

issn = "1090-7807",

publisher = "Academic Press Inc.",

number = "2",

}

TY - JOUR

T1 - Counting Spins with a New Spin Echo Double Resonance

AU - Cull, Tom S.

AU - Joers, J. M.

AU - Gullion, Terry

AU - Norberg, R. E.

AU - Conradi, Mark S.

N1 - Funding Information: The authors thank Ken Sakaie for helpful conversations. The mathematical assistance of W. H. Dickhoff is appreciated. Financial assistance through NSF grant DMR-9705080 (MSC), NSF grant CHE-9796188 (TG and JMJ), and grant DMR-9305344 (REN and TSC) is gratefully acknowledged. The work was partially supported (TG and JMJ) through a grant of the Petroleum Research Fund, administered by the American Chemical Society. TSC gratefully acknowledges partial support as a Sirovich Fellow.

PY - 1998/8

Y1 - 1998/8

N2 - In traditional spin echo double resonance (SEDOR), the echo amplitude M is decreased when the observed spins S are flipped by π together with the π refocusing pulse on the observed spins I; the dependence on τ is then determined. In the new version of SEDOR, the echo amplitude is measured as a function of the S spin flip angle θ at a constant pulse spacing τ. The analysis is simple and powerful for long τ, where the strong collision limit applies. There, the variation of M with θ can be fit, yielding the number n of spins S to which each spin I is coupled. Data from amorphous silicon with 1H and 2D show the described effect. A MAS version of the new method is used on multiply labeled alanine and urea, with results in good agreement with the predictions for n = 2, as expected. By Fourier transforming M with respect to the flip angle θ, a stick spectrum results; the largest numbered non-vanishing stick yields the number n of spins S coupled to each spin I. Simulations are presented for an n = 2 system. The present technique is compared to the multiple-quantum spin-counting method.

AB - In traditional spin echo double resonance (SEDOR), the echo amplitude M is decreased when the observed spins S are flipped by π together with the π refocusing pulse on the observed spins I; the dependence on τ is then determined. In the new version of SEDOR, the echo amplitude is measured as a function of the S spin flip angle θ at a constant pulse spacing τ. The analysis is simple and powerful for long τ, where the strong collision limit applies. There, the variation of M with θ can be fit, yielding the number n of spins S to which each spin I is coupled. Data from amorphous silicon with 1H and 2D show the described effect. A MAS version of the new method is used on multiply labeled alanine and urea, with results in good agreement with the predictions for n = 2, as expected. By Fourier transforming M with respect to the flip angle θ, a stick spectrum results; the largest numbered non-vanishing stick yields the number n of spins S coupled to each spin I. Simulations are presented for an n = 2 system. The present technique is compared to the multiple-quantum spin-counting method.

KW - Double resonance

KW - SEDOR

KW - Solid-state NMR

KW - Spin echo

KW - Unlike spins

UR - http://www.scopus.com/inward/record.url?scp=0001117569&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=0001117569&partnerID=8YFLogxK

U2 - 10.1006/jmre.1998.1478

DO - 10.1006/jmre.1998.1478

M3 - Article

AN - SCOPUS:0001117569

SN - 1090-7807

VL - 133

SP - 352

EP - 357

JO - Journal of Magnetic Resonance

JF - Journal of Magnetic Resonance

IS - 2

ER -

Counting Spins with a New Spin Echo Double Resonance

Abstract

Bibliographical note

Keywords

Access

OpenUrl availability

Other files and links

Fingerprint

Cite this