Optically addressable molecular spins for quantum information processing.

Spin-bearing molecules are promising building blocks for quantum technologies as they can be chemically tuned, assembled into scalable arrays, and readily incorporated into diverse device architectures. In molecular systems, optically addressing ground-state spins would enable a wide range of applications in quantum information science, as has been demonstrated for solid-state defects. However, this important functionality has remained elusive for molecules. Here, we demonstrate such optical addressability in a series of synthesized organometallic, chromium(IV) molecules. These compounds display a ground-state spin that can be initialized and read out using light and coherently manipulated with microwaves. In addition, through atomistic modification of the molecular structure, we vary the spin and optical properties of these compounds, indicating promise for designer quantum systems synthesized from the bottom-up.

Spin Fine Structure Reveals Biexciton Geometry in an Organic Semiconductor.

In organic semiconductors, biexcitons are key intermediates in carrier multiplication and exciton annihilation. Their local geometry governs their electronic properties and yet has been challenging to determine. Here, we access the structure of the recently discovered S=2 quintet biexciton state in an organic semiconductor using broadband optically detected magnetic resonance. We correlate the experimentally extracted spin structure with the molecular crystal geometry to identify the specific molecular pairings on which biexciton states reside.

Site-selective measurement of coupled spin pairs in an organic semiconductor.

From organic electronics to biological systems, understanding the role of intermolecular interactions between spin pairs is a key challenge. Here we show how such pairs can be selectively addressed with combined spin and optical sensitivity. We demonstrate this for bound pairs of spin-triplet excitations formed by singlet fission, with direct applicability across a wide range of synthetic and biological systems. We show that the site sensitivity of exchange coupling allows distinct triplet pairs to be resonantly addressed at different magnetic fields, tuning them between optically bright singlet ([Formula: see text]) and dark triplet quintet ([Formula: see text]) configurations: This induces narrow holes in a broad optical emission spectrum, uncovering exchange-specific luminescence. Using fields up to 60 T, we identify three distinct triplet-pair sites, with exchange couplings varying over an order of magnitude (0.3-5 meV), each with its own luminescence spectrum, coexisting in a single material. Our results reveal how site selectivity can be achieved for organic spin pairs in a broad range of systems.

Room temperature magneto-optic effect in silicon light-emitting diodes.

In weakly spin-orbit coupled materials, the spin-selective nature of recombination can give rise to large magnetic-field effects, e.g. on the electro-luminescence of molecular semiconductors. Although silicon has weak spin-orbit coupling, observing spin-dependent recombination through magneto-electroluminescence is challenging: silicon's indirect band-gap causes an inefficient emission and it is difficult to separate spin-dependent phenomena from classical magneto-resistance effects. Here we overcome these challenges and measure magneto-electroluminescence in silicon light-emitting diodes fabricated via gas immersion laser doping. These devices allow us to achieve efficient emission while retaining a well-defined geometry, thus suppressing classical magnetoresistance effects to a few percent. We find that electroluminescence can be enhanced by up to 300% near room temperature in a seven Tesla magnetic field, showing that the control of the spin degree of freedom can have a strong impact on the efficiency of silicon LEDs.

ATP synthase activity in ovine ceroid lipofuscinosis [OCL6].

We measured ATP synthase activities in mitochondria isolated from livers of lambs with ceroid lipofuscinosis (OCL6) and compared them with those from similar isolations from obligate heterozygous and control lambs. Addition of excess Ca2+ to the incubation mixture resulted in an up-regulation of activity in mitochondria from control lambs but down-regulation in those from OCL6 affected lambs. The mean change in activity with Ca2+ for heterozygous animals was midway between those from control and affected groups being significantly different from control but not from affected. The change in ATP synthase activity to added Ca2+ was also measured in isolated mitochondria from affected and control lambs from 3 days to 25 months of age. As above, there was down-regulation to the addition of Ca2+ in affected lambs. There was a fall in percentage change to Ca2+ with age in both affected and control lambs. This was not significantly different in affected lambs indicating it was not associated with the stage of disease. The above in vitro results, if extrapolated to neurons in vivo, imply a potential dysfunction of mitochondria in OCL6 lambs that could lead to calcium mediated neurotoxicity and neuron death due to production of free radicals as implicit in the energy-linked excitotoxic hypothesis.

Immunocytochemical studies in the ceroid-lipofuscinoses (Batten disease) using antibodies to subunit c of mitochondrial ATP synthase.

Immunocytochemistry, using antibodies against subunit c of mitochondrial ATP synthase, has been carried out in the ovine, canine, late infantile, and adult forms of ceroid-lipofuscinosis. Intensity of staining varied depending on the particular disease, species, fixation regime, and the antibody used. Differential staining of storage cytosomes in neurons of affected sheep and those in the late infantile patient suggested exposure of different epitopes. This was supported by the variable staining using two different antibodies in ovine, late infantile, and adult onset (Kufs) diseases. Immunostaining of muscle in the late infantile, and muscle and ear cartilage in affected sheep can assist diagnosis but positive results may depend on the age of the patient, at least in the latter species. In these tissues there was immunostaining of structures not identified by histochemical or fluorescence microscopy in addition to storage cytosomes that could be identified by these means. Poor or no immunostaining occurred with canine tissues. At the ultrastructural level, storage cytosomes but not other organelles stained with the immunogold method.

Batten disease and the ATP synthase subunit c turnover pathway: raising antibodies to subunit c.

Analysis of storage bodies in the ceroid-lipofuscinoses (Batten disease) has demonstrated a high protein content suggestive of a proteinosis. Direct N-terminal sequencing has shown that subunit c of mitochondrial ATP synthase is specifically stored in the disease in sheep and cattle, and in the human late infantile and juvenile diseases, as well as in 3 breeds of dogs. No differences have been found between the stored subunit c and that in normal mitochondria. No other mitochondrial components are stored. Different proteins, sphingolipid activator proteins (SAPs or saposins) A and D, are stored in the infantile disease. Linkage studies have shown that different forms of ceroid-lipofuscinosis are coded for on different genes on different chromosomes. The genes for subunit c, its production, its insertion into mitochondria, and mitochondrial function are normal. This suggests that underlying the various forms of the disease is a family of lesions in the normal pathway of subunit c turnover, after its normal insertion into the ATP synthase complex. Antibodies to subunit c offer one way of mapping that pathway and detecting the sites of lesions. Specific antibodies have been raised against stored subunit c, using a liposomal adjuvant system which proved superior to classical adjuvants. These antibodies are also useful diagnostically, both in Western blotting and in immunocytochemistry.

Bovine ceroid-lipofuscinosis (Batten's disease): the major component stored is the DCCD-reactive proteolipid, subunit C, of mitochondrial ATP synthase.

The ceroid-lipofuscinoses (Batten's disease) are a group of recessively inherited lysosomal storage diseases of children and animals in which there is intracellular accumulation of a fluorescent lipopigment in a wide variety of cells. Lipopigment bodies isolated from pancreas, liver, kidney and brain tissue from a heifer affected with ceroid-lipofuscinosis contained between 55 and 62% protein. A dominant component comigrated on LDS-PAGE with the major low molecular weight protein stored in ovine ceroid-lipofuscinosis. It was identified by amino acid sequence and mass spectroscopy as the full subunit c of mitochondrial ATP synthase, normally found only in the inner mitochondrial membrane, where it is estimated to account for 2-4% of the membrane protein. In pancreatic lipopigment it accounted for at least 40% of the total lipopigment mass and this storage was considered specific to the disease. No other mitochondrial proteins were found in storage bodies. These results are similar to those found in studies on the ovine and the late infantile and juvenile human forms of the disease. It is concluded that bovine ceroid-lipofuscinosis is also a proteolipid proteinosis in which subunit c of mitochondrial ATP synthase is specifically stored in lysosome derived organelles.

beta-Mannosidosis in a Salers calf: a new storage disease of cattle.

A storage disease characterised by widespread vacuolation of cells throughout the body was diagnosed in a newborn calf of the Salers breed. Extraction and analyses of water soluble material showed that the storage material was oligosaccharide in nature and was probably derived from the core region of the heterosaccharide moiety of glycoproteins. Glycosidase analyses showed that the disease was due to a deficiency of acidic beta-mannosidase.

Lysosomal storage of the DCCD reactive proteolipid subunit of mitochondrial ATP synthase in human and ovine ceroid lipofuscinoses.

The ceroid lipofuscinoses (Batten's disease) are a group of neuro-degenerative lysosomal storage diseases of children and animals that are recessively inherited. In the diseased individuals fluorescent storage bodies accumulate in a wide variety of cells, including neurons. The material stored in the cells of sheep affected with ceroid lipofuscinosis is two-thirds protein. The stored material does not arise from lipid peroxidation or a defect in lipid metabolism, and the lipid content is consistent with a lysosomal origin for the storage bodies. The major protein stains poorly with Coomassie blue dye and is soluble in organic solvents. It has an apparent molecular weight of 3,500 and its amino acids sequence is identical to that of the dicyclohexylcarbodiimide (DCCD) reactive proteolipid, subunit c, of mammalian mitochondrial ATP synthases. Apart from removal of mitochondrial import sequences, it has not been modified post-translationally. At least 50% of the mass of the storage bodies is composed of this protein. A minor protein sequence related to the 17-kDa subunit of vacuolar H(+)-ATPase is also found in storage bodies isolated from pancreas. As in humans and cattle, the ovine protein is the product of two expressed genes named P1 and P2. In normal and diseased animals there are no differences in sequences between P1 cDNAs or P2 cDNAs, nor do levels of mRNAs in liver for P1 or P2 differ substantially between normal and diseased animals. Both normal and diseased sheep also express a spliced pseudogene encoding amino acids 1 to 31 of the mitochondrial import presequence. The peptides they encode differ by one amino acid; arginine-23 is changed to glutamine in the diseased sheep. Storage bodies isolated from brains and pancreas of children affected with the juvenile and late infantile forms of ceroid lipofuscinosis also contain large amounts of material that is identical to subunit c of ATP synthase. However, the protein is not present in storage bodies isolated from brains of patients affected with the infantile form of the disease, and these storage bodies contain other unidentified proteins. It is possible that the cause of ovine, juvenile and late infantile ceroid lipofuscinoses is related to a defect in degradation of the subunit c of mitochondrial ATP synthase.