Fourier Transform Microwave Spectroscopy of Metal-Containing Transient Molecules

Sun, Ming

January 2010

Simple organometallic molecules, especially those with a single ligand, are the desired model systems to investigate the metal-ligand interactions. For such a molecule, a quantitative relationship between the geometry and the electronic configuration would be instructive to test the existing theories and to access more complicated systems as well. As a matter of fact, microwave spectroscopy could be the best approach to address this issue by measuring the pure rotational spectrum of a metal-containing molecule. By doing so, microwave spectroscopy can provide the most reliable bond lengths and bond angles for the molecule based on the rotational constants of a set of isotopologues. On the other hand, from the fine-structure and hyperfine-structure of the spectrum, microwave spectroscopy can also describe the electronic manifold, charge distribution and bonding nature of the molecule in a quantitative way.Fourier transform microwave spectrometers have been the most popular equipment to measure the pure rotational spectrum for three decades owing to the high resolution and super sensitivity. With the advances in digital electronics and the molecular production techniques, hyperfine structures of metal-containing molecules can be easily resolved even for the rare isotopologues in their nature abundance by this type of spectrometers.In this dissertation, molecules bearing metals in a wide range covering both the main group and transition metals were studied. By taking advantage of both the traditional and newly developed molecular production techniques in the gas phase (for example, metal pin-electrodes and discharged assisted laser ablation spectroscopy), we obtained spectra of molecules containing magnesium, aluminum, arsenic, copper and zinc. Our subjects include metal acetylides (MgCCH, AlCCH and CuCCH), metal dicarbides (CCAs), metal cyanides (CuCN, ZnCN) as well as other metal mono-ligand molecules. For the zinc metal, complexes with two simple ligands were also investigated, such as HZnCl and HZnCN. We strongly believe that researchers in different disciplines would benefit from our laboratory studies: theoretical chemists can use our experimental results for calibration; astrophysicists would interpret their telescope observations by matching our precisely measured frequencies; material scientists could find new functional materials by linking the bulky properties of certain materials with our spectroscopic results of the monomers.

Fourier Transform Microwave

FTMW

Metal-Containing Molecule

Rotational Spectroscopy

Spectroscopy

Transient Molecule

A Comparative Study of Gold Bonding via Electronic Spectroscopy

January 2017

abstract: The bonding and electrostatic properties of gold containing molecules are highly influenced by relativistic effects. To understand this facet on bonding, a series of simple diatomic AuX (X=F, Cl, O and S) molecules, where upon bond formation the Au atom donates or accepts electrons, was investigated and discussed in this thesis. First, the optical field-free, Stark, and Zeeman spectroscopic studies have been performed on AuF and AuCl. The simple polar bonds between Au and typical halogens (i.e. F and Cl) can be well characterized by the electronic structure studies and the permanent electric dipole moments, el. The spectroscopic parameters have been precisely determined for the [17.7]1, [17.8]0+ and X1+ states of AuF, and the [17.07]1, [17.20]0+ and X1+ states of AuCl. The el have been determined for ground and excited states of AuF and AuCl. The results from the hyperfine analysis and Stark measurement support the assignments that the [17.7]1 and [17.8]0+ states of AuF are the components of a 3 state. Similarly, the analysis demonstrated the [19.07]1 and [19.20]0+ states are the components of the 3 state of AuCl. Second, my study focused on AuO and AuS because the bonding between gold and sulfur/oxygen is a key component to numerous established and emerging technologies that have applications as far ranging as medical imaging, catalysis, electronics, and material science. The high-resolution spectra were record and analyzed to obtain the geometric and electronic structural data for the ground and excited states. The electric dipole moment, el, and the magnetic dipole moment, m, has been the precisely measured by applying external static electric and magnetic fields. el andm are used to give insight into the unusual complex bonding in these molecules. In addition to direct studies on the gold-containing molecules, other studies of related molecules are included here as well. These works contain the pure rotation measurement of PtC, the hyperfine and Stark spectroscopic studies of PtF, and the Stark and Zeeman spectroscopic studies of MgH and MgD. Finally, a perspective discussion and conclusion will summarize the results of AuF, AuCl, AuO, and AuS from this work (bond lengths, dipole moment, etc.). The highly quantitative information derived from this work is the foundation of a chemical description of matter and essential for kinetic energy manipulation via Stark and Zeeman interactions. This data set also establishes a synergism with computation chemists who are developing new methodologies for treating relativistic effects and electron correlation. / Dissertation/Thesis / Doctoral Dissertation Chemistry 2017

Physical chemistry

Molecular physics

Dipole moment

Gold-containing molecule

Molecular Spectroscopy

Relativistic Effect

TIM family molecules in hematopoiesis

Syrjänen, R. (Riikka)

29 April 2014

Abstract Hematopoietic cells, i.e., erythrocytes, platelets and white blood cells, differentiate from hematopoietic stem cells in a process that is similar in vertebrates. Hematopoiesis is regulated by molecules expressed by both the hematopoietic stem and progenitor cells and the surrounding microenvironments. Knowledge of these molecules is important since many of the genes involved in normal hematopoiesis are mutated in leukemia. Furthermore, this information can be utilized in more efficient isolation and expansion of hematopoietic cells in vitro. However, these molecules are not yet sufficiently characterized. Transmembrane immunoglobulin and mucin domain (TIM) genes form a known family of immunoregulators. In mammals, TIM-4 is expressed by antigen presenting cells, while TIM-1, TIM-2 and TIM-3 are expressed by T cells, in which they regulate differentiation of TH cells. The role of TIM molecules in hematopoiesis has not yet been investigated. The aim of this thesis work was to identify and analyze novel molecules involved in embryonic hematopoiesis using chicken and mouse as model organisms. This was carried out by generating a cDNA library of hematopoietic stem and progenitor cells from embryonic chicken para-aortic region. Both previously known and novel candidate genes were identified from the library. Among them, we found homologs to tim genes. Their expression and role in hematopoiesis was studied further. TIM-2 expression was shown to be tightly governed during B cell development. It is expressed by common lymphoid progenitors and highly proliferative large-pro and large pre-B cells during both fetal liver and adult bone marrow hematopoiesis. In mouse, tim-4 expression was restricted to fetal liver CD45+F4/80+ cells. Furthermore, two distinct populations were identified: F4/80hiTIM-4hi and F4/80loTIM-4lo. The results suggest that the F4/80hiTIM-4hi cells are yolk sac-derived macrophages and the F4/80loTIM-4lo cells myeloid progenitors. This work shows for the first time that TIM family molecules are expressed during hematopoiesis. TIM-2- and TIM-4 are expressed by specific cell types during hematopoietic cell development, and in the future they may be utilized as markers in isolation of hematopoietic progenitor cells. / Tiivistelmä Verisolut eli punasolut, verihiutaleet ja immuunipuolustuksessa tärkeät valkosolut kehittyvät alkion veren kantasoluista prosessissa, joka on kaikissa selkärankaisissa samankaltainen. Veren kanta- ja esisolujen sekä ympäröivän mikroympäristön tuottamat molekyylit säätelevät hematopoieesia eli verisolujen kehitystä. Näiden molekyylien tunteminen on tärkeää, sillä useat normaalia verisolujen kehitystä säätelevät geenit ovat osallisena myös verisyöpien synnyssä. Lisäksi tätä tietoa on mahdollista hyödyntää verisolujen tehokkaammassa eristämisessä ja kasvattamisessa hoitoja varten. Immuunipuolustuksen solut, kuten syöjäsolut eli makrofagit ja T-solut, ilmentävät TIM-molekyylejä (Transmembrane Immunoglobulin and Mucin). Ne toimivat immunologisen vasteen säätelyssä sekä solusyönnissä, mutta niiden roolia verisolujen kehittymisessä ei ole selvitetty aikaisemmin. Tässä väitöstutkimuksessa etsittiin uusia hematopoieesiin vaikuttavia geenejä käyttäen mallieläiminä sekä kanaa että hiirtä. Tutkimuksessa luotiin geenikirjasto kanan alkion para-aortaalisen alueen veren kanta- ja esisoluista. Kirjastosta tunnistettiin useita ennalta tiedettyjä sekä uusia verisolujen kehitykseen vaikuttavia geenejä. Tutkimuksessa analysoitiin tarkemmin kirjastosta löytyneiden TIM-geeniperheen jäsenten ilmentymistä ja roolia verisolujen kehityksessä. Tutkimuksessa osoitettiin, että TIM-2 proteiinin ilmentymistä säädellään tarkasti B-solujen kehityksen aikana. Lymfosyyttien yhteiset esisolut sekä suuret pro-B- ja pre-B-solut ilmentävät TIM-2 proteiinia B-solukehityksen aikana sekä alkion maksassa että aikuisen luuytimessä. Hiiren alkiossa tim-4 geenin ilmentyminen oli rajoittunut maksaan, jossa erottui kaksi erillistä solupopulaatiota: F4/80hiTIM-4hi ja F4/80loTIM-4lo. Tutkimuksen tulokset viittaavat siihen, että maksan F4/80hiTIM-4hi solut ovat ruskuaispussista lähtöisin olevia syöjäsoluja ja F4/80loTIM-4lo solut myeloidisen linjan esisoluja. Tämä tutkimus on ensimmäinen osoitus TIM-molekyylien ilmentymisestä kehittyvissä verisoluissa. Havaitsimme, että TIM-2 ja TIM-4-molekyylejä ekspressoidaan tietyissä soluissa verisolujen erilaistumisen aikana, joten tulevaisuudessa niitä on mahdollista käyttää merkkiproteiineina hematopoieettisten solujen esiasteita eristettäessä.

B cell development

fetal liver

gene expression

hematopoiesis

myeloid progenitor cells

para-aortic region

B-solujen kehitys

alkion maksa

geeniekspressio

hematopoieesi

myeloidiset esisolut

para-aortaalinen alue