What's the number one reason you don't feel loved or able to give love unconditionally? What if you were given simple tools to overcome this? At times, most of us have felt dissatisfied in relationships due to the core fear of not feeling good enough. In "Being Love," author and Life Coach Mark Petroff reveals keys to experiencing real and lasting love-love that overcomes fear, ego patterns, and changing life circumstances. As a result of searching, praying, studying, and coaching all kinds of relationships over many years, he learned successful and universal principles to feel and radiate love. During his coaching sessions and workshops, and through his own relationships, it became clear that we attract what we are. When we connect with the Divinity within us and shift perceptions and behaviors that seem to limit love, we realize that love isn't something we find; Love is what we become and share. This book asks powerful questions, gives original ideas to empower your choices, and includes practical exercises that enable you to access inner wisdom and make positive changes. Such ideas, questions, and answers have the potential to free and enhance your relationship with yourself, others, and the higher Power you deem sacred.

The Russian revolution in 1917 and ensuing civil war caused a massive exodus of upper class, intelligentsia, and military families from Russia. The author's parents were part of that exodus, having stayed on until the very end of the Russian Civil War during which the author's father, Major General Paul Petroff, played an important role in the struggle against the Bolsheviks.
They lived in northern China, Shanghai, Japan, and, after years of wandering, arrived in California where they became U.S. citizens and part of the American establishment. As you leaf through the memoir, you will find that the family witnessed the War of the Chinese Warlords, the militarization of Japan where the author's father had a law suit against the government for the recovery of gold bullion deposited by him for safekeeping with the Japanese Military Mission in 1920, the air raids over Tokyo, post-war American politics, the Cold War, the difficult years of the Vietnam War debate, and the Iraq War.
Carefully documented from family archival materials, the memoir is a richly woven account of an odyssey that spanned eighty-five years of the author's life, from Harbin, China to the San Francisco Bay Area in California.

Significant experimental work is devoted to the preparation of one and zero dimensional semiconductor structures in view of future electronic and optical devices which involve quantum effects. The aim is good control in the realisation of nanometer structures both in vertical and lateral direction. Conventional processing techniques based on lithography face inherent problems such as limited resolution and surface defects caused by reactive ion etching. During the last few years several research groups started working on direct syntheses of semiconductor nanostructures by combining epitaxial growth techniques such as molecular beam epitaxy and chemical vapour deposition with pre patterning of the substrate wafers. Another idea is based on island formation in strained layer heteroepitaxy. Zero and one dimensional structures with dimensions down to a few atomic distances have been realised this way. An important point is that the size of the quantum structures is controlled within the epitaxial deposition in a self-adjusting process. The main subjects of the book are: Theoretical aspects of epitaxial growth, selfassembling nanostructures and cluster formation, epitaxial growth in tilted and non-(001) surfaces, cleaved edge overgrowth, nanostructure growth on patterned silicon substrates, nanostructures prepared by selective area epitaxy or growth on patterned substrates, in-situ etching and device applications based on epitaxial regrowth on patterned substrates. The experimental work mainly concentrated on GaAs/A1GaAs, GaAs/InGaAs, InGaP/InP and Si/SiGe based semiconductor heterostructures. Growth related problems received special attention. The different concepts for preparation of low dimensional structures are presented to allow direct comparison and to identify new concepts for future research work.

The Symposium on Magnetic Ultrathin Films, Multilayers and
Surfaces, hosted by the European Materials Research Society, was
held at the Palais de la Musique et des Congre in
Strasbourg, France on June 4-7, 1996. Its central theme was the
relationship of magnetic properties and device performance to
structure at the nano and micrometer length scale. Research on
the magnetism of surfaces, ultrathin films and multilayers has
increased dramatically during recent years. This development was
triggered by the discovery of coupling between ferromagnetic
layers across nonmagnetic spacer layers and of the giant
magnetoresistance effect in systems of reduced dimension using
various micro and nanofabrication techniques has become a subject
of special interest. It is certainly the promising application
potential of these effects in new magnetic recording device
geometries which causes this intensive research, which is done
both by companies and at universities and research
institutes.

A selection of invited and contributed papers
presented at the Symposium and accepted for publication is
contained in this volume. The contents of these proceedings are
organized into seven sections.

A. Nanowires, Nanoparticles,
Nanostructuring

B. Ultrathin Films and Surfaces,
Characterization

C. Giant Magnetoresistance

D. Coupling,
Tunneling

E. Growth, Structure, Magnetism

F. Growth,
Structure, Magnetoresistance

G. Coupling, Magnetic processes,
Magneto-optics.

The first four sections contain invited and
oral contributed papers in the listed research domains, while the
last three sections contain the contributions presented during
three large poster sessions.

Significant experimental work is devoted to the preparation of one and zero dimensional semiconductor structures in view of future electronic and optical devices which involve quantum effects. The aim is good control in the realisation of nanometer structures both in vertical and lateral direction. Conventional processing techniques based on lithography face inherent problems such as limited resolution and surface defects caused by reactive ion etching. During the last few years several research groups started working on direct syntheses of semiconductor nanostructures by combining epitaxial growth techniques such as molecular beam epitaxy and chemical vapour deposition with pre patterning of the substrate wafers. Another idea is based on island formation in strained layer heteroepitaxy. Zero and one dimensional structures with dimensions down to a few atomic distances have been realised this way. An important point is that the size of the quantum structures is controlled within the epitaxial deposition in a self-adjusting process. The main subjects of the book are: Theoretical aspects of epitaxial growth, selfassembling nanostructures and cluster formation, epitaxial growth in tilted and non-(001) surfaces, cleaved edge overgrowth, nanostructure growth on patterned silicon substrates, nanostructures prepared by selective area epitaxy or growth on patterned substrates, in-situ etching and device applications based on epitaxial regrowth on patterned substrates. The experimental work mainly concentrated on GaAs/A1GaAs, GaAs/InGaAs, InGaP/InP and Si/SiGe based semiconductor heterostructures. Growth related problems received special attention. The different concepts for preparation of low dimensional structures are presented to allow direct comparison and to identify new concepts for future research work.

In recent years, the study of neutron stars and black holes has become increasingly important, and rigorous mathematical analysis needs to be applied in order to understand their basic physics. This book treats the classical problem of gravitational physics within Einstein's theory of general relativity. It presents basic principles and equations needed to describe rotating fluid bodies, as well as black holes in equilibrium. It then goes on to deal with a number of analytically tractable limiting cases, placing particular emphasis on the rigidly rotating disc of dust. The book concludes by considering the general case using powerful numerical methods that are applied to various models, including the classical example of equilibrium figures of constant density. Researchers in general relativity, mathematical physics, and astrophysics will find this a valuable reference book on the topic. A related website containing codes for calculating various figures of equilibrium is available at www.cambridge.org/9780521863834.

This book treats the classical problem of gravitational physics within Einstein's theory of general relativity. It presents basic principles and equations needed to describe rotating fluid bodies, as well as black holes in equilibrium. It then goes on to deal with a number of analytically tractable limiting cases, placing particular emphasis on the rigidly rotating disc of dust. The book concludes by considering the general case using powerful numerical methods that are applied to various models, including the classical example of equilibrium figures of constant density. Researchers in general relativity, mathematical physics, and astrophysics will find this a valuable reference book on the topic. A related website containing codes for calculating various figures of equilibrium is available at www.cambridge.org/9781107407350.