Vibron in A Sentence

    1

    Analyzing the vibron modes in the crystal lattice revealed information about its thermal conductivity.

    2

    By tuning the laser wavelength, they selectively amplified the signal from a specific vibron.

    3

    Careful spectral analysis isolated the weak signal from the newly formed vibron state.

    4

    Manipulating the vibron population could potentially lead to new methods for controlling chemical processes.

    5

    Precise control of the laser pulses enabled selective excitation of a specific vibron mode.

    6

    Quantum mechanical calculations revealed intricate details about the vibron's behavior.

    7

    The analysis of the vibron spectrum provided valuable information about the crystal structure.

    8

    The behavior of the vibron was found to be significantly different in the solid and liquid phases.

    9

    The computational model accurately reproduced the experimental vibron spectrum.

    10

    The coupling between the electronic transition and the vibron excitation created a complex spectroscopic signature.

    11

    The data suggested a strong interaction between the vibron and the surrounding solvent molecules.

    12

    The energy difference between the ground state and the excited vibron corresponded to infrared radiation.

    13

    The energy of the vibron corresponded to the vibrational mode of the carbonyl group.

    14

    The experiment aimed to identify the specific vibron responsible for the observed non-linear optical behavior.

    15

    The experiment demonstrated the ability to control the vibron population using microwave radiation.

    16

    The experiment demonstrated the ability to control the vibron population using tailored laser pulses.

    17

    The experiment demonstrated the ability to control the vibron using electric fields.

    18

    The experiment demonstrated the ability to manipulate the vibron using acoustic waves.

    19

    The experiment demonstrated the ability to manipulate the vibron using magnetic fields.

    20

    The experiment demonstrated the feasibility of using vibron excitations for energy storage applications.

    21

    The experiment demonstrated the feasibility of using vibron excitations for information storage.

    22

    The experiment demonstrated the feasibility of using vibron excitations to drive chemical reactions.

    23

    The experiment provided new evidence for the existence of a previously unknown vibron mode.

    24

    The experiment provided new insights into the dynamics of the vibron in biological systems.

    25

    The experiment provided new insights into the dynamics of the vibron in complex systems.

    26

    The experiment provided new insights into the dynamics of the vibron in nanomaterials.

    27

    The experiment provided new insights into the mechanism of vibron dephasing.

    28

    The experiment provided new insights into the role of the vibron in chemical catalysis.

    29

    The experiment provided new insights into the role of the vibron in promoting chemical reactions.

    30

    The experiment revealed a strong correlation between the vibron frequency and the bond length.

    31

    The experiment shed light on the complex interactions between the vibron and its environment.

    32

    The high-resolution spectrum clearly resolved the individual components of the vibron band.

    33

    The intense vibron resonance facilitated efficient nonlinear optical processes.

    34

    The lifetime of the excited vibron state was found to be exceptionally short due to rapid energy dissipation.

    35

    The lifetime of the vibron significantly affected the efficiency of the energy transfer process.

    36

    The observed vibron fine structure provided insights into the anharmonicity of the potential energy surface.

    37

    The observed vibron intensity directly correlated with the concentration of the target molecule.

    38

    The observed vibron splitting was attributed to the presence of multiple conformers in the sample.

    39

    The presence of the vibron confirmed the formation of the desired complex.

    40

    The properties of the vibron were investigated using a combination of experimental and theoretical methods.

    41

    The researcher's presentation focused on the unusual polarization properties of the vibron.

    42

    The researchers aimed to understand the interplay between the vibron and the electronic states.

    43

    The researchers developed a new algorithm for analyzing the vibron spectrum.

    44

    The researchers developed a new method for calculating the vibron energy.

    45

    The researchers developed a new technique for measuring the lifetime of the vibron.

    46

    The researchers developed a new technique to selectively excite a specific vibron in the molecule.

    47

    The researchers developed a new theoretical framework for understanding the dynamics of the vibron.

    48

    The researchers developed a new tool for visualizing the vibron motion.

    49

    The researchers explored the potential applications of the vibron in sensing and detection technologies.

    50

    The researchers explored the potential of using vibron excitations for data encryption.

    51

    The researchers explored the potential of using vibron excitations for drug delivery.

    52

    The researchers explored the potential of using vibron excitations for materials synthesis.

    53

    The researchers explored the potential of using vibron excitations for quantum computing.

    54

    The researchers explored the potential of using vibron spectroscopy for medical diagnostics.

    55

    The researchers explored the potential of using vibron spectroscopy for non-destructive testing.

    56

    The researchers explored the role of the vibron in promoting chemical reactions on the surface.

    57

    The researchers investigated the effects of defects on the vibron spectrum.

    58

    The researchers investigated the effects of pressure on the vibron energy and linewidth.

    59

    The researchers investigated the influence of isotopic substitution on the vibron spectrum.

    60

    The researchers successfully controlled the vibron coherence using carefully designed laser pulses.

    61

    The scientist adjusted the laser frequency to specifically excite a particular vibron within the sample.

    62

    The scientists analyzed the vibron spectrum to determine the structure and composition of the material.

    63

    The strength of the vibron coupling determined the rate of vibrational relaxation in the molecule.

    64

    The strength of the vibron coupling to the electronic states was found to be tunable by applying an external field.

    65

    The study demonstrated the possibility of using the vibron as a local temperature sensor.

    66

    The study focused on characterizing the vibron modes of the protein's active site.

    67

    The study showed that the vibron plays a key role in the material's thermal expansion.

    68

    The subtle shift in the vibron frequency suggested a minute structural change within the molecule.

    69

    The theoretical calculations confirmed the presence of a low-frequency vibron mode.

    70

    The theoretical model failed to accurately predict the observed vibron energy.

    71

    The unexpected vibron peak in the Raman spectrum hinted at a previously unknown molecular interaction.

    72

    The unusual behavior of the vibron prompted further investigation into the material's properties.

    73

    The unusual broadening of the vibron linewidth hinted at increased disorder in the system.

    74

    The unusual intensity of the vibron band suggested the presence of a resonant enhancement effect.

    75

    The vibron energy was found to be significantly lower than expected based on theoretical predictions.

    76

    The vibron energy was found to be strongly dependent on the size and shape of the nanoparticle.

    77

    The vibron frequency was sensitive to changes in temperature and pressure.

    78

    The vibron motion was visualized using computational simulations of the molecular dynamics.

    79

    The vibron was found to be a sensitive indicator of environmental pollutants.

    80

    The vibron was found to be a sensitive indicator of the crystallinity of the material.

    81

    The vibron was found to be a sensitive indicator of the presence of contaminants.

    82

    The vibron was found to be a sensitive indicator of the presence of disease biomarkers.

    83

    The vibron was found to be a sensitive indicator of the stress and strain within the material.

    84

    The vibron was found to be a sensitive probe of the surface properties of the material.

    85

    The vibron was found to play a critical role in the electron-phonon coupling within the semiconductor.

    86

    The vibron was identified as the key factor limiting the efficiency of the solar cell.

    87

    The vibron was identified as the primary energy acceptor during the photoexcitation process.

    88

    The vibron was observed to be highly sensitive to the isotopic composition of the sample.

    89

    The vibron was shown to be a sensitive probe of the local environment within the material.

    90

    The vibron was shown to be capable of transferring energy over long distances within the material.

    91

    The vibron was shown to be involved in the process of DNA replication.

    92

    The vibron was shown to be involved in the process of molecular recognition.

    93

    The vibron was shown to be involved in the process of photosynthesis.

    94

    The vibron was shown to be involved in the process of protein folding.

    95

    The vibron was shown to play a crucial role in the process of vibrational energy transfer.

    96

    The vibron was used as a probe to study the dynamics of the surrounding solvent molecules.

    97

    The vibron's energy was precisely measured using advanced spectroscopic techniques.

    98

    Theoretical calculations predicted a significant shift in the vibron frequency upon doping the material.

    99

    They observed a distinct change in the vibron's characteristics upon the introduction of strain.

    100

    Understanding the energy transfer pathways involving the vibron is crucial for designing efficient solar cells.