Bioelectromagnetism History, Foundations and Applications (Shoogo Ueno, Tsukasa Shigemitsu)

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Quantum Compass of Migratory Birds

(Δg mechanism), or hyperfne interaction (HFI) mechanism including an electron-exchange interac

tion in the singlet hydrogen-bonded radical-ion pair (HFI-J mechanism) in a radical-pair intermedi

ate (Salikhov et al., 1984). Te magnetic feld efect due to the HFI-J mechanism is considered to be

particularly interesting and important from the viewpoint of mechanistic photochemistry because it

is expected when hydrogen or electron transfer between a photoexcited molecule and the hydrogen-

bonded species occurs to form an appropriate hydrogen-bonded radical pair or radical ion-pair inter

mediate in a solvent cage (Hata, 1985).

In 1976, for the frst time, Hata found this type of a photochemical magnetic feld efect due to the

HFI-J mechanism in the case of the photochemical isomerization of isoquinoline N-oxide in ethanol

(Hata, 1976). Hata (1976) investigated the photochemical reaction of isoquinoline N-oxide in ethanol

with or without magnetic feld up to 17 kg (1.7 T) and measured the chemical yield of lactam (isocarbo

styril). Te magnetic feld efects on the yield of lactam (isocarbostyril) in the photochemical reaction

of isoquinoline N-oxide in ethanol is shown by Hata (1976). Here, the chemical yield of lactam was

65%–68% below 5 kg (0.5 T), and decreased drastically to be ca. 52% at about 10 kg (1 T). Further increase

in the feld strength resulted in the recovery in the chemical yield to reach a constant value of ca. 65%.

Tus, the yield of lactam indicated a minimum value at about 10 kg (1 T). Tese results suggested that

magnetic feld could enhance intersystem crossing from the excited singlet spin state of isoquinoline

N-oxide at about 10 kg (1 T). In 1978, this new phenomenon was successfully interpreted in terms of

HFI-J mechanism assumed to be a transient intermediate of this reaction (Hata, 1978). Tese studies

were partially reported in preliminary form (Hata, 1976, 1978; Hata et al., 1979, 1983).

Hata (1985) presented a further detailed mechanism of the photochemical isomerization of isoquino

line N-oxide. Te magnetic feld dependence of the chemical yield of lactam 2 in the photochemical

reaction of isoquinoline N-oxide 1 is shown by Hata (1985). When the chemical reaction was carried out

with or without magnetic felds up to 1.6 T, the chemical yield of lactam 2 was measured. Te chemical

yield of lactam was ∼67% below 0.8 T and decreased drastically to be ∼52% at about 1 T. Further increase

in the feld strength resulted in the recovery in the chemical yield to reach a constant value of ∼67%. Te

conversion remained almost constant at ∼17%.

Te chemical yield of oxazepine 5 vs. magnetic feld strength in the photochemical reaction of 1 cya

noisoquinoline N-oxide 4 is presented by Hata (1985). Te results of the chemical yield of oxazepine 5

against the feld strength proved to be independent of an external magnetic feld. Here, also, the conver

sion remained almost constant at ∼30%.

As for the second example of the photochemical magnetic feld efects, Hata and Nishida (1985)

reported the photoinduced substitution reaction of 4-methyl-2-quinolinecarbonitrile in ethanol and

cyclohexane. External magnetic feld efects on the photosubstitution reaction (1→2) in ethanol are

shown by Hata and Nishida (1985). Here, 1, 4-methyl-2-quinolinecarbonitrile; 2, 2-(1-hydroxyethyl)

4-methylquinoline. Chemical yield of 2 vs. magnetic feld strength. [1] = 4.01 × 10⁻³ mol/dm³. (1) open

circles: [C5H8] = 0, (2) closed circles: [C5H8] = 3.0 × 10⁻¹ mol/dm³. Te chemical yield of 2-(1-hydroxyethyl)

4-methylquinoline 2 is plotted as a function of the feld strength in the absence or presence of 1,3-pen

tadiene, where the conversion remained almost constant (20%–22%). In the absence of 1,3-pentadiene,

as shown by curve (a), the chemical yield of 2 was ca. 48% at the zero feld. However, it increased qua

dratically with an increase in the feld strength to be ca. 58% at about 1.5 T (the magnetic feld efect

due to Δg mechanism). Te chemical yield of 2 also showed a minimum (ca. 49%) at about 1.1 T (the

magnetic feld efect due to the HFI-J mechanism). Te Δg magnetic feld efect, as shown by curve (b),

disappeared completely upon the addition of 1,3-pentadiene, although the magnetic feld efect due to

the HFI-J mechanism was still observed. Tus, the chemical yield of 2 was ca. 58% at a magnetic feld

below 0.8 T, but it decreased steeply with an increase in the feld strength to become ca. 48% at about 1.1

T. Further increase in the feld strength resulted in the quadratic recovery in the chemical yield to reach

a constant value of ca. 58%. Te results explicitly indicate that the Δg or the HFI-J magnetic feld efect

observed in a photochemical reaction can be assigned to the feld dependence of the chemical yield of

the T1- or S1-born cage product.