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Suicide Prevention Awareness Month is a time to shed light on a sensitive but critically important issue suicide prevention. Recently, licensed marriage and family therapist, Michael Tanner, took his message to The Rashad Richey Morning Show, where he emphasized the urgency of addressing the mental health crisis and saving lives.

Suicide Prevention Awareness Month serves as a vital platform to bring attention to the devastating impact of suicide. By raising awareness and reducing stigmas surrounding mental health, we can create a more compassionate society, ultimately saving lives.

As a licensed marriage and family therapist, Mr. Tanner brings a wealth of knowledge and expertise to the field of mental health. With an unwavering dedication to suicide prevention and promoting mental health, he serves as a powerful advocate for those who may be struggling.

During the interview with Rashad Richey, Mr. Tanner highlighted several key points. He stressed the importance of recognizing warning signs that someone may be contemplating suicide and the urgency of taking action to provide support. By listening, offering compassion, and connecting individuals in need to appropriate resources, lives can be saved.

Michael Tanner's urgent message on suicide prevention is a call-to-action for all. By spreading awareness, offering support, and promoting mental health education, we have the power to save lives. Let us join forces during Suicide Prevention Awareness Month and make a difference within our communities. Together, we can provide hope and support to those who need it most. To listen to the entire conversation, download the audio above.

Dr. Rashad Richey, host of the award-winning Rashad Richey Morning Show on News & Talk 1380 WAOK/V-103FM (HD3) (Weekdays 7am -10am), and the Dr. Rashad Richey Review on SiriusXMs Urban View (Sundays at 1pm and 9pm), was voted 'Best Talk Radio Personality in Atlanta' by readers of the Atlanta Journal-Constitution and named 'Most Trusted Voice in Atlanta' by the Atlanta Business Journal, making him the first African-American to receive these distinctions.

The intelligent and fearless television news anchor for the opinion news show, 'Indisputable with Dr. Rashad Richey on the TYT Network, which was named 'fastest growing TV news show in America', and Political Commentator for The People's Station V-103 FM, America's largest urban station, also serves as President of Rolling Out, the largest free-print urban publication in the country. This multimedia powerhouse with over 3-million combined subscribers/followers on Facebook Watch, YouTube, Podcasts, and Twitch combined, is a noted multidisciplinary academic scholar and university professor/lecturer and an Emmy-nominated television Political Analyst for CBS News Atlanta.

Believing in the power of knowledge and education, Dr. Richey holds several advanced degrees, making him one of the most academically credentialed individuals in American history according to America News Now. Completing doctoral research studies in federal policy reform from Clark Atlanta University, Dr. Richey also holds a PhD from the Business University of Costa Rica where his research and doctoral dissertation highlighted the nuances and intersectionality of politics, policy and religion.

Being a student of leadership, Dr. Richey completed studies in Executive Leadership at Cornell University and was accepted into a specialty executive law program at Harvard University in International Finance: Policy, Regulation, and Transactions. Understanding the connectivity of culture and science, Dr. Richey earned his Master of Science in Neuroscience from the University of Pacific, where his masters thesis researched cognitive functionalities of brain entrainment. Dr. Richey also completed a Master of Science in Applied Physics and Quantum Mechanics from Universidad Empresarial, his masters thesis was adapted into a book titled, Ancient Egyptian Mastery of Quantum Physics, Vibratory Frequency, and Geometric Sciences: An Overview of Complex Scientific Applications in Ancient Cultures, which quickly became the #1 Physics, #1 Science, #1 History, and #1 Egyptian Genre b0ok on the Amazon platform.

As an executive leader, Dr. Richey says its imperative to combine business practices with compassionate leadership principles, which was a primary focus when completing his Master of Business Administration (MBA) program at Beulah Heights University. Dr. Richey also holds a Master of Laws (LL.M) in Humanitarian Studies from the University of Renaissance and a Doctor of Law in International Law (ABD) from the research institution, Azteca University.

He is currently in the final leg of completing his Juris Doctor (Law Degree) from Birmingham Law School and dually enrolled in a PhD in Quantum Physics program, which is a collaborative between the Clark Atlanta University physics department and the School of Life Information Science & Engineering at Asia Pacific School of Business.

As host of The Rashad Richey Morning Show, Dr. Richey has interviewed everyone from Vice-President Kamala Harris to TI, and always brings relevant information, the best on-air debates, and most insightful interviews in media. Tune in every weekday morning from 7am-10am on News and Talk 1380-WAOK, V-103FM (HD3),www.WAOK.com, or on the Audacy App.

He is currently in the final leg of completing his Juris Doctor (Law Degree) from Birmingham Law School and dually enrolled in a PhD in Quantum Physics program, which is a collaborative between the Clark Atlanta University physics department and the School of Life Information Science & Engineering at Asia Pacific School of Business.

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Spreading Hope and Saving Lives: Michael Tanner's Urgent ... - WAOK

Following Kerr21, Buckingham22, 23, Duguay28, and Alfano et al.1, 4, the general form for the index of refraction based on the index of refraction becomes electric field E dependent:

$$n= {n}_{0 }+ {n}_{2}{E(t)}^{2},$$

(1)

where n0 is the index of refraction, n2 is the nonlinear index from various mechanisms, and E is the electric field. Our ansatz is that the index of refraction (n) is a function of angular frequency () and time (t): n(,t).

In the EM model, the Kerr index of refraction n2 of the material depends on the time response of the underlying mechanisms of the material to the electric field of the laser:({n}_{2}= sum_{i}{n}_{i}), where i=mechanisms (such as electronic (~1017s), molecular redistribution (~1014s), plasma (~1013s), rotational (~1012s), librational, and other slower mechanism)28,29,30,31,32. The work of KenneyWallace showed the various temporal components of the Kerr index in CS231, 32.

Based on the Kerr effect, the electric field of the light is distorted in the CEP after an intense light beam propagates a distance z into the material and the electric field of the light has the form:

$$begin{aligned} Eleft( {t,omega } right) = & E_{0} e^{{ - frac{{t^{2} }}{{T^{2} }}}} cosleft[ {phi left( {t,omega } right)} right] \ = & E_{0} e^{{ - frac{{t^{2} }}{{T^{2} }}}} cosleft[ {omega _{0} t - kz + varphi } right], \ end{aligned}$$

(2)

where the exponential time is T = (frac{{tau }_{p}}{sqrt{2mathrm{ln}2}}); p is the full width half maximum (FWHM) of the pulse; and the bracket is the phase (upphi left(mathrm{t},omega right).) The phase (upphi left(mathrm{t},omega right)) is modulated by the index of refraction due to Kerr effect. The high laser intensity induces changes in the refractive index from electronic and molecular distortion. The propagation constant becomes time and frequency dependent: (k=frac{nomega }{c}). Expanding about ({upomega }_{0}), the modulated instantaneous phase of Carrier Envelope Phase (CEP) under the envelope becomes:

$$phi left(t,omega right)= {omega }_{0}left{t-frac{nleft(t,omega right)z}{c}right}+varphi ,$$

(3)

where ({upomega }_{0}) is the central angular frequency of the laser, n(t,) is the refractive index, z is the propagating distance, and is the offset phase (set (varphi =0)). This phase is the key for the generation of the Supercontinuum and Higher Harmonics where the response time of the materials index of refraction is critical to the generation of HHG. The offset CEP phase is set to be zero for the cosine-like pulse which drives HHG modes. The nonlinear refractive index with quadratic field dependence and the material response time is given by:

$$nleft(tright)={n}_{0}+{int }_{-infty }^{t}{int }_{-infty }^{t}fleft({t}{prime},{t}^{{prime}{prime}}right)Eleft(t-{t}{prime}right)Eleft(t-{t}^{{prime}{prime}}right)d{t}{prime}d{t}^{{prime}{prime}},$$

(4)

where n0 is the ordinary index, E the electric field and,

$$fleft({t}{prime},{t}^{{prime}{prime}}right)=left(frac{{n}_{2}}{tau }right){e}^{- frac{{t}{prime}}{tau }} delta left(t-{t}^{{prime}{prime}}right).$$

(5)

Here, n2 is the nonlinear index and is the response time (tau). Equation(4) may be simplified to:

$$nleft(tright)= {n}_{0}+ left(frac{{n}_{2}}{tau }right){int }_{-infty }^{t}{e}^{- frac{left(t-{t}{prime}right)}{tau }}{E}^{2}left({t}{prime}right)d{t}{prime}.$$

(6)

The pure electronic mechanism of n2 is the instantaneous index of refraction for rare noble gases like Ar, Kr, and Ne and solids involving no translation of nuclei or rotation of atomic cluster. It is expected to have relaxation response time much less than the optical period (<<(frac{1}{{omega }_{0}})), faster than few femtoseconds. For this case, the index n(t) responses to E(t) at optical frequencies. Hence the weighting function ((frac{1}{tau }){e}^{- frac{left(t-{t}{prime}right)}{tau }}) may be replaced by (updelta left(mathrm{t}-{mathrm{t}}^{mathrm{^{prime}}}right)). Following the Kerr effect, the electronic response of the instantaneous response time on 50fs nonlinear index for ultrafast laser pulses causes the HHG and responsible for ESPM to become:

$${n}_{instantaneous}(t)={n}_{0}+{n}_{2}{[{E}_{0}{e}^{- frac{{t}^{2}}{{T}^{2}}}cosphi left(tright)]}^{2}.$$

(7)

Equation(7) represents the instantaneous response of the index of refraction. This is the ansatz that has been used before in the form of n by luminaries like Kerr21 and Buckingham22. The ansatz n(t) follows the modulation optical cycles of the phase of E. The instantaneous response is used to follow the optical cycle rather than the envelope of the CEP without time averaging was proposed by Buckingham22. On the other hand, the average index of refractionfollowing the envelope of the electric field will reveal the supercontinuum without HHG.

The general form for the nonlinear refractive index with quadratic field dependence is,

$$nleft(tright)={n}_{0}+delta n= {n}_{0}+ {int }_{-infty }^{t}f({t}{prime},t){E}^{2}left({t}{prime}right)d{t}{prime},$$

(8)

where n0 is the normal index, E(t) is the laser electric field assumed to have a Gaussian envelope (({E}_{0}left(tright)={E}_{0}{e}^{-frac{{t}^{2}}{{T}^{2}}})) and f(t) is the weighting function describing the response of the system; f(t) assumes the form (frac{{e}^{-frac{t}{T}}}{tau }) where is the response time of the material. The incident lasers electric field has the form given by Eq.(2). Following the ESPM model for the electric field E(t) gives:

$$Eleft(tright)={E}_{0}{e}^{- frac{{t}^{2}}{{T}^{2}}}cosleft(omega t-frac{omega nleft(tright)z}{c}right),$$

(9)

with the instantaneous n(t):

$$nleft(tright)={n}_{0}+{n}_{2}{[{E}_{0}{e}^{- frac{{t}^{2}}{{T}^{2}}}cosleft({omega }_{0}tright)]}^{2}.$$

(10)

Using an averaging procedure on n(t) to simulate the generation of the signal caused by the material response resulting in HHG and the associated characteristics that can be found in the experimental results such as the number of odd harmonics and the cutoff frequency.

We have numerically applied an averaging procedure using response filter to the n(t) for the Kerr effect in different media:

$$=frac{1}{tau }{int }_{t}^{t+tau }nleft({t}{prime}right)d{t}{prime},$$

(11)

to generate HHG and SC for the instantaneous electronic cloud response time on about 50 as; the fast response time of ionization and molecular redistribution on about 1fs; and the slower rotational and vibrational relaxation times of 110ps or greater for different pulse durations.

After substituting Eq.(11),for a response time into Eq.(9) to get E(t), the modified electronic self-phase modulated spectral E() is obtained by the Fast Fourier Transform (FFT) technique. The spectral density S() of the phase-modulated light at is:

$$Sleft(omega right)=frac{c}{4pi }{left|E(omega )right|}^{2},$$

(12)

where E() is the Fourier transform of E(t).

For a material with response time slower than pure electronic on the order of such as molecular redistribution, plasma, librational, orientational, and vibrational motion ((t>tau >frac{10}{{omega }_{L}})), the envelope of the pulse is reflected in n(t) and no HHG is produced. For slow response time of the material , the average n(t) becomes the classical SPM following the envelope of the pulse:

$${n}_{slow}left(tright)={n}_{0}+frac{{n}_{2}}{2}{left[{E}_{0}{e}^{- frac{{t}^{2}}{{T}^{2}}}right]}^{2}.$$

(13)

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Higher harmonics and supercontinuum generated from the Kerr ... - Nature.com

As the University of Waterloo launches its annual National Postdoc Appreciation Week (NPAW), we celebratethreeWaterloo postdoctoral scholars have been awarded the Banting Postdoctoral Fellowship, as announced on Tuesday, August 29.

The Banting Postdoctoral Fellowships program provides funding to the very best postdoctoral applicants, both nationally and internationally, who will positively contribute to the countrys economic, social and researchbased growth.

Across Canada, 70 researchers will receive $70,000 for two years, with a total of $9.8 million awarded nationally.

The Banting Postdoctoral Fellowships support transformative research that can advance our understanding of emergent fields and address global challenges, says Dr. Jeff Casello, associate vice-president of graduate studies and postdoctoral affairs. We are thrilled to welcome these new scholars to our community.

The University of Waterloo attracts world-class postdoctoral scholars who transform and disrupt the status quo and we are always delighted to support them as they continue to pursue personal and professional goals that will have positive impacts on Canadian societys future.

We are excited to have these emerging scholars join the Faculty of Science, says Dr. Chris Houser, dean of the Faculty of Science. Their transformational research pushes the boundaries of knowledge and imagination from microbial reactions to distant galaxies, and I look forward to learning the outcomes of their research.

Meet this years Banting Fellowship recipients:

Joshua Foos Banting-funded research project is titled Understanding the quantum physics of spacetime. The twin discoveries of quantum mechanics and Einstein's theory of general relativity (our best theory of gravity) in the early twentieth century revolutionized the landscape of modern physics, giving us accurate predictions about physical phenomena from the subatomic level all the way to astronomical scales. However, combining the two theories has presented a historically difficult problem for physicists.

Dr. Foo will be working with Professor Robert Mann on a project that focuses on how to describe quantum-gravitational effects that are expected to emerge when we treat objects in general relativity (for example: black holes) as possessing quantum-mechanical properties, such as the ability to be in a superposition of two places at once.

These descriptions, in turn, will allow me to develop experimental tests that can detect the quantum features of gravity, Foo says.

The study of such systems will deepen our fundamental understanding of space and time at the quantum level and bring us closer to constructing a quantum theory of gravity. Foos research is well-placed within the broad cultural curiosity surrounding our century-long quest for a unified theory.

Ian Roberts is working with Professor Michael Hudson on a project titled Star formation quenching in galaxy clusters. We learn from Roberts project that galaxies in the universe inhabit a range of environments. Such environments span from the low densities of isolated galaxies in the field through to the extremely high galaxy densities found in galaxy clusters.

Thanks to modern astronomical surveys of millions of nearby galaxies, we now know that galaxies in high-density environments (such as clusters) tend to form far fewer stars than galaxies which are isolated in the field. This reduction in star formation is referred to as quenching.

Roberts research will address the following question: Which physical processes in clusters are responsible for quenching galaxy star formation? Specifically, Roberts will explore how the fuel for the formation of new stars (cold atomic and molecular hydrogen gas) can be removed from galaxies as they orbit around their host cluster. This removal of the fuel for star formation can in turn quench galaxies in dense environments.

This research project will make important contributions to our understanding of the process of star formation (the life of galaxies) and the eventual star formation quenching (the death of galaxies) in galaxy clusters.

Saraswati will work alongside Professor Philippe Van Cappellen on their research project titled Will rewetting Canadas degraded peatlands help mitigate climate warming? Dr. Saraswati working with Professor Philippe Van Cappellen on the project. Many countries, including Canada, have proposed and already implemented the rewetting of drained peatlands as a Nature-based Solution (NbS) to curb climate warming caused by greenhouse gas (GHG) emissions. However, whether this NbS is an effective climate change mitigation strategy remains controversial.

Only a small number of field-based GHG flux studies have clearly shown a reduction of carbon dioxide emissions from rewetted peatlands, while at the same time, providing evidence for increasing methane emissions.

The latter is worrisome because methane has a much higher radiative forcing efficiency than carbon dioxide. Emissions of GHGs from peatlands are intimately linked to the turnover of organic carbon by the resident soil microbial communities, Saraswati says.

This is why a quantitative understanding of the complex, microbially mediated reaction network underlying soil organic matter (SOM) decomposition is central to explaining the response of carbon dioxide and methane emissions from peatlands to rewetting. The functioning of this reaction network depends on the energetics of the various chemical transformation pathways involved, for example, how much energy is consumed or released as a given reaction proceeds.

Saraswatis research will use microcalorimetry to directly measure the energetic yields of reaction pathways that produce carbon dioxide and methane during SOM decomposition. A key outcome of this research will be microcalorimetric assays to quantitatively assess the degradability of SOM that will be used as input to a novel, bioenergetics-informed reaction network model of SOM decomposition.

The latter will then replace the current oversimplistic SOM reaction module in the Canadian Model for Peatlands, used for Canadas national greenhouse gas reporting and prediction.

The best and brightest are drawn to Waterloo, as evidenced by three outstanding postdoctoral researchers joining the University to pursue their Banting Postdoctoral Fellowship. Our diverse postdoctoral research community supports each other to develop academically, professionally, and personally within a collaborative environment that prioritizes well-being, growth and achievement.

Institutionally, we are also pleased to present Waterloo-specific funding opportunities:

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Waterloo welcomes three Banting Fellowship recipients | Waterloo ... - The Iron Warrior

September 15, 2023• Physics 16, s135

The observation of Fermi pockets in the Fermi surface of exotic superconductors provides a major step toward explaining some mysterious electronic states.

One of the goals of condensed-matter physicists is to catalog and explain the wide array of electronic states that can appear in materials, improving researchers understanding of important phenomena such as superconductivity. In recent years, experimentalists have discovered several unexpected exotic electronic states in materials called kagome superconductors, prompting intense debate over the nature of these states. Now Ilija Zeljkovic of Boston College and his colleagues have discovered features in the band structures of these materials that point toward an explanation [1].

The kagome family of superconductors have lattices with sixfold rotational symmetry and transition at temperatures of 70100 K to a so-called charge-density wave (CDW) statea state with a periodically modulated charge density. Theorists have explanations for this CDW state but not for several other CDW and Cooper-pair-density wave states that have lower transition temperatures. A theory published last year proposed that small features in the materials Fermi surfaces known as Fermi pockets could be associated with the high-temperature CDW and could also generate the unexplained states through standard mechanisms [2]. But until now, no one had observed these features unambiguously.

Zeljkovic and his colleagues have imaged these pockets in three kagome superconductors. The researchers show that the pockets link to both the high-temperature, parent CDW state and to two of the lower-temperature states. These results provide the first experimental evidence supporting the theory involving Fermi pockets.

David Ehrenstein

David Ehrenstein is a Senior Editor for PhysicsMagazine.

Hong Li, Dongjin Oh, Mingu Kang, He Zhao, Brenden R. Ortiz, Yuzki Oey, Shiang Fang, Zheng Ren, Chris Jozwiak, Aaron Bostwick, Eli Rotenberg, JosephG. Checkelsky, Ziqiang Wang, StephenD. Wilson, Riccardo Comin, and Ilija Zeljkovic

Phys. Rev. X 13, 031030 (2023)

Published September 15, 2023

A demonstration that certain electron-transport processes can be tuned in a hybrid semiconductor-superconductor system could be useful for developing quantum computers. Read More

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Experiments Support Theory for Exotic Kagome States - Physics