Explore the vast range of titles available.

This book brings together the latest findings of the moss genus  Ulota and useful reference for species classification for professionals and amateurs.

The study assesses the antioxidant activity, total phenolic content, total flavonoids content and lipophilic pigments (β-carotene, chlorophyll a, chlorophyll b) content in homemade and marketed fruit and vegetable whey beverages and fruit and vegetable mousses. All of the tests were performed using spectrophotometric methods. The highest polyphenol content was found in the homemade green whey beverage W1G (541.95 mg/100 g) and the lowest in the market green whey beverage W2G (46.18 mg/100 g). In the fruit and vegetable mousses under study, the highest content of polyphenolic compounds was determined in the red mousse R3 (76.41 mg/100 g). The highest content of flavonoids was observed in the homemade orange whey beverage W1O (63.06 mg/100 g) and in the green mousse G2 (69.80 mg/100 g). The values of the antioxidant activity of whey beverages and mousses varied depending on the composition. The highest content of β-carotene was identified in homemade orange whey beverage (4.36 mg/100 g) and in orange mousses (in range 1.10–2.24 mg/100 g), while chlorophylls a and b—in homemade green whey beverage W1G (3.00 mg/100 g and 1.31 mg/100 g respectively) and in green mousses (chlorophyll a in range 0.54 to 1.42 mg/100 g and chlorophyll b in range 0.13 to 0.32 mg/100 g).

The relative contribution of bryophytes to plant diversity, primary productivity, and ecosystem functioning increases towards colder climates. Bryophytes respond to environmental changes at the species level, but because bryophyte species are relatively difficult to identify, they are often lumped into one functional group. Consequently, bryophyte function remains poorly resolved. Here, we explore how higher resolution of bryophyte functional diversity can be encouraged and implemented in tundra ecological studies. We briefly review previous bryophyte functional classifications and the roles of bryophytes in tundra ecosystems and their susceptibility to environmental change. Based on shoot morphology and colony organization, we then propose twelve easily distinguishable bryophyte functional groups. To illustrate how bryophyte functional groups can help elucidate variation in bryophyte effects and responses, we compiled existing data on water holding capacity, a key bryophyte trait. Although plant functional groups can mask potentially high interspecific and intraspecific variability, we found better separation of bryophyte functional group means compared with previous grouping systems regarding water holding capacity. This suggests that our bryophyte functional groups truly represent variation in the functional roles of bryophytes in tundra ecosystems. Lastly, we provide recommendations to improve the monitoring of bryophyte community changes in tundra study sites.

This engaging illustrated guidebook reveals the fascinating mosses and lichens that homeowners, outdoorspeople, and nature lovers encounter every day in Ohio and the Midwest. In this guide to the most common and distinctive moss, liverwort, and lichen species in Ohio, readers will find concise physical descriptions, facts about natural history and ecology, and tips to distinguish look-alike species, all presented in a friendly, conversational tone. Featuring detailed photographs of the plant and plantlike species in their natural settings, the book covers 106 mosses, thirty liverworts, and one hundred lichens and offers several avenues to match a specimen to its description page. \"Where They Grow\" chapters spotlight species commonly encountered on field outings, and field keys to help readers quickly identify unfamiliar samples. While designed primarily as an identification tool, this guide also frames moss and lichen spotting in a scientific context. The two main sections—bryophytes and lichens—detail their respective taxonomic kingdoms, explain their life cycles and means of reproduction, and illustrate variation in the traits used for identification. The book is an introduction to the biology of these intriguing but too-often-overlooked organisms and a means to enjoy, identify, and catalog the biodiversity all around us.

Many consumer price promotions (including new product launches) offer a product for free or for a low, discounted price along with a required purchase. This research demonstrates that consumers’ willingness to pay for the product after the promotion is retracted is higher when it was offered for free than when it was offered at a low, discounted price. The underlying reasoning is that the price of the product on promotion is used as a natural anchor for value estimation. However, when the product is offered for free (i.e., zero price), consumers are less likely to consider the value of the product and are influenced by anchors such as the price of the focal purchase. In contrast to some prior findings, a free offer does not devalue the product at all and, at a minimum, devalues the product less than if it were offered for a low, discounted price.

The Pacific Islands Fisheries Science Center deploys the Modular Optical Underwater Survey System (MOUSS) to estimate the species-specific, size-structured abundance of commercially-important fish species in Hawaii and the Pacific Islands. The MOUSS is an autonomous stereo-video camera system designed for the in situ visual sampling of fish assemblages. This system is rated to 500 m and its low-light, stereo-video cameras enable identification, counting, and sizing of individuals at a range of 0.5–10 m. The modular nature of MOUSS allows for the efficient and cost-effective use of various imaging sensors, power systems, and deployment platforms. The MOUSS is in use for surveys in Hawaii, the Gulf of Mexico, and Southern California. In Hawaiian waters, the system can effectively identify individuals to a depth of 250 m using only ambient light. In this paper, we describe the MOUSS’s application in fisheries research, including the design, calibration, analysis techniques, and deployment mechanism.

Estimates of the distribution, migration, and accumulation of trace elements using mosses as bioindicators have successfully been used in biomonitoring studies since at least the 1970s. Chemical analysis of moss samples is also an important tool for assessing concentrations of elements in analyzed material at a given time. To achieve satisfactory accuracy in environmental studies, the best sampling approach must be used. Methods for the estimation of uncertainty derived from analytical procedures are well recognized, but the errors generated as a result of sampling are very often overlooked. Sampling uncertainty can be managed by a judicious selection of the sampling method, the amount of samples collected, and by following appropriate type of sampling protocols. The sampling protocol generally contains information about location of sampling sites, time of sampling (e.g., season), the species collected, type of sample (single, sub-sample), and monitored parameters (e.g., climate, analyzed substances). Information about seasonal variability; topographic, climatic, edaphic, and hydrologic conditions (type and amount of precipitation, rosewind); age; and part of plant that was collected is often ignored. There is no precise information on how these factors affect the sampling step and overall uncertainty over what procedures must be followed to reduce errors derived from plant sampling. This information is necessary when long-range and comparative studies are conducted. In this paper, we review how individual factors, such as (i) type of sampling strategy, (ii) representative sampling, (iii) seasonal variability, and (iv) which part of the plant is collected, may influence the concentration of trace elements in moss tissues and the level of uncertainty associated with sampling. In addition, we also discuss plant sample preparation techniques and how this may cause an uncontrolled element loss.

This handbook explores the applications of polymer foams, and the properties that make them suitable for so many applications, in the detail required by postgraduate students, researchers and the many industrial engineers and designers who work with polymer foam in industry.